/* from src/prism2/download/prism2dl.c * * utility for downloading prism2 images moved into kernelspace * * Copyright (C) 1999 AbsoluteValue Systems, Inc. All Rights Reserved. * -------------------------------------------------------------------- * * linux-wlan * * 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 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. * * -------------------------------------------------------------------- * * Inquiries regarding the linux-wlan Open Source project can be * made directly to: * * AbsoluteValue Systems Inc. * info@linux-wlan.com * http://www.linux-wlan.com * * -------------------------------------------------------------------- * * Portions of the development of this software were funded by * Intersil Corporation as part of PRISM(R) chipset product development. * * -------------------------------------------------------------------- */ /*================================================================*/ /* System Includes */ #include <linux/ihex.h> #include <linux/slab.h> /*================================================================*/ /* Local Constants */ #define PRISM2_USB_FWFILE "prism2_ru.fw" MODULE_FIRMWARE(PRISM2_USB_FWFILE); #define S3DATA_MAX 5000 #define S3PLUG_MAX 200 #define S3CRC_MAX 200 #define S3INFO_MAX 50 #define S3ADDR_PLUG (0xff000000UL) #define S3ADDR_CRC (0xff100000UL) #define S3ADDR_INFO (0xff200000UL) #define S3ADDR_START (0xff400000UL) #define CHUNKS_MAX 100 #define WRITESIZE_MAX 4096 /*================================================================*/ /* Local Types */ struct s3datarec { u32 len; u32 addr; u8 checksum; u8 *data; }; struct s3plugrec { u32 itemcode; u32 addr; u32 len; }; struct s3crcrec { u32 addr; u32 len; unsigned int dowrite; }; struct s3inforec { u16 len; u16 type; union { hfa384x_compident_t version; hfa384x_caplevel_t compat; u16 buildseq; hfa384x_compident_t platform; } info; }; struct pda { u8 buf[HFA384x_PDA_LEN_MAX]; hfa384x_pdrec_t *rec[HFA384x_PDA_RECS_MAX]; unsigned int nrec; }; struct imgchunk { u32 addr; /* start address */ u32 len; /* in bytes */ u16 crc; /* CRC value (if it falls at a chunk boundary) */ u8 *data; }; /*================================================================*/ /* Local Static Definitions */ /*----------------------------------------------------------------*/ /* s-record image processing */ /* Data records */ unsigned int ns3data; struct s3datarec s3data[S3DATA_MAX]; /* Plug records */ unsigned int ns3plug; struct s3plugrec s3plug[S3PLUG_MAX]; /* CRC records */ unsigned int ns3crc; struct s3crcrec s3crc[S3CRC_MAX]; /* Info records */ unsigned int ns3info; struct s3inforec s3info[S3INFO_MAX]; /* S7 record (there _better_ be only one) */ u32 startaddr; /* Load image chunks */ unsigned int nfchunks; struct imgchunk fchunk[CHUNKS_MAX]; /* Note that for the following pdrec_t arrays, the len and code */ /* fields are stored in HOST byte order. The mkpdrlist() function */ /* does the conversion. */ /*----------------------------------------------------------------*/ /* PDA, built from [card|newfile]+[addfile1+addfile2...] */ struct pda pda; hfa384x_compident_t nicid; hfa384x_caplevel_t rfid; hfa384x_caplevel_t macid; hfa384x_caplevel_t priid; /*================================================================*/ /* Local Function Declarations */ static int prism2_fwapply(const struct ihex_binrec *rfptr, wlandevice_t *wlandev); static int read_fwfile(const struct ihex_binrec *rfptr); static int mkimage(struct imgchunk *clist, unsigned int *ccnt); static int read_cardpda(struct pda *pda, wlandevice_t *wlandev); static int mkpdrlist(struct pda *pda); static int plugimage(struct imgchunk *fchunk, unsigned int nfchunks, struct s3plugrec *s3plug, unsigned int ns3plug, struct pda * pda); static int crcimage(struct imgchunk *fchunk, unsigned int nfchunks, struct s3crcrec *s3crc, unsigned int ns3crc); static int writeimage(wlandevice_t *wlandev, struct imgchunk *fchunk, unsigned int nfchunks); static void free_chunks(struct imgchunk *fchunk, unsigned int *nfchunks); static void free_srecs(void); static int validate_identity(void); /*================================================================*/ /* Function Definitions */ /*---------------------------------------------------------------- * prism2_fwtry * * Try and get firmware into memory * * Arguments: * udev usb device structure * wlandev wlan device structure * * Returns: * 0 - success * ~0 - failure ----------------------------------------------------------------*/ int prism2_fwtry(struct usb_device *udev, wlandevice_t *wlandev) { const struct firmware *fw_entry = NULL; printk(KERN_INFO "prism2_usb: Checking for firmware %s\n", PRISM2_USB_FWFILE); if (request_ihex_firmware(&fw_entry, PRISM2_USB_FWFILE, &udev->dev) != 0) { printk(KERN_INFO "prism2_usb: Firmware not available, but not essential\n"); printk(KERN_INFO "prism2_usb: can continue to use card anyway.\n"); return 1; } printk(KERN_INFO "prism2_usb: %s will be processed, size %zu\n", PRISM2_USB_FWFILE, fw_entry->size); prism2_fwapply((const struct ihex_binrec *)fw_entry->data, wlandev); release_firmware(fw_entry); return 0; } /*---------------------------------------------------------------- * prism2_fwapply * * Apply the firmware loaded into memory * * Arguments: * rfptr firmware image in kernel memory * wlandev device * * Returns: * 0 - success * ~0 - failure ----------------------------------------------------------------*/ int prism2_fwapply(const struct ihex_binrec *rfptr, wlandevice_t *wlandev) { signed int result = 0; struct p80211msg_dot11req_mibget getmsg; p80211itemd_t *item; u32 *data; /* Initialize the data structures */ ns3data = 0; memset(s3data, 0, sizeof(s3data)); ns3plug = 0; memset(s3plug, 0, sizeof(s3plug)); ns3crc = 0; memset(s3crc, 0, sizeof(s3crc)); ns3info = 0; memset(s3info, 0, sizeof(s3info)); startaddr = 0; nfchunks = 0; memset(fchunk, 0, sizeof(fchunk)); memset(&nicid, 0, sizeof(nicid)); memset(&rfid, 0, sizeof(rfid)); memset(&macid, 0, sizeof(macid)); memset(&priid, 0, sizeof(priid)); /* clear the pda and add an initial END record */ memset(&pda, 0, sizeof(pda)); pda.rec[0] = (hfa384x_pdrec_t *) pda.buf; pda.rec[0]->len = cpu_to_le16(2); /* len in words */ pda.rec[0]->code = cpu_to_le16(HFA384x_PDR_END_OF_PDA); pda.nrec = 1; /*-----------------------------------------------------*/ /* Put card into fwload state */ prism2sta_ifstate(wlandev, P80211ENUM_ifstate_fwload); /* Build the PDA we're going to use. */ if (read_cardpda(&pda, wlandev)) { printk(KERN_ERR "load_cardpda failed, exiting.\n"); return 1; } /* read the card's PRI-SUP */ memset(&getmsg, 0, sizeof(getmsg)); getmsg.msgcode = DIDmsg_dot11req_mibget; getmsg.msglen = sizeof(getmsg); strcpy(getmsg.devname, wlandev->name); getmsg.mibattribute.did = DIDmsg_dot11req_mibget_mibattribute; getmsg.mibattribute.status = P80211ENUM_msgitem_status_data_ok; getmsg.resultcode.did = DIDmsg_dot11req_mibget_resultcode; getmsg.resultcode.status = P80211ENUM_msgitem_status_no_value; item = (p80211itemd_t *) getmsg.mibattribute.data; item->did = DIDmib_p2_p2NIC_p2PRISupRange; item->status = P80211ENUM_msgitem_status_no_value; data = (u32 *) item->data; /* DIDmsg_dot11req_mibget */ prism2mgmt_mibset_mibget(wlandev, &getmsg); if (getmsg.resultcode.data != P80211ENUM_resultcode_success) printk(KERN_ERR "Couldn't fetch PRI-SUP info\n"); /* Already in host order */ priid.role = *data++; priid.id = *data++; priid.variant = *data++; priid.bottom = *data++; priid.top = *data++; /* Read the S3 file */ result = read_fwfile(rfptr); if (result) { printk(KERN_ERR "Failed to read the data exiting.\n"); return 1; } result = validate_identity(); if (result) { printk(KERN_ERR "Incompatible firmware image.\n"); return 1; } if (startaddr == 0x00000000) { printk(KERN_ERR "Can't RAM download a Flash image!\n"); return 1; } /* Make the image chunks */ result = mkimage(fchunk, &nfchunks); /* Do any plugging */ result = plugimage(fchunk, nfchunks, s3plug, ns3plug, &pda); if (result) { printk(KERN_ERR "Failed to plug data.\n"); return 1; } /* Insert any CRCs */ if (crcimage(fchunk, nfchunks, s3crc, ns3crc)) { printk(KERN_ERR "Failed to insert all CRCs\n"); return 1; } /* Write the image */ result = writeimage(wlandev, fchunk, nfchunks); if (result) { printk(KERN_ERR "Failed to ramwrite image data.\n"); return 1; } /* clear any allocated memory */ free_chunks(fchunk, &nfchunks); free_srecs(); printk(KERN_INFO "prism2_usb: firmware loading finished.\n"); return result; } /*---------------------------------------------------------------- * crcimage * * Adds a CRC16 in the two bytes prior to each block identified by * an S3 CRC record. Currently, we don't actually do a CRC we just * insert the value 0xC0DE in hfa384x order. * * Arguments: * fchunk Array of image chunks * nfchunks Number of image chunks * s3crc Array of crc records * ns3crc Number of crc records * * Returns: * 0 success * ~0 failure ----------------------------------------------------------------*/ int crcimage(struct imgchunk *fchunk, unsigned int nfchunks, struct s3crcrec *s3crc, unsigned int ns3crc) { int result = 0; int i; int c; u32 crcstart; u32 crcend; u32 cstart = 0; u32 cend; u8 *dest; u32 chunkoff; for (i = 0; i < ns3crc; i++) { if (!s3crc[i].dowrite) continue; crcstart = s3crc[i].addr; crcend = s3crc[i].addr + s3crc[i].len; /* Find chunk */ for (c = 0; c < nfchunks; c++) { cstart = fchunk[c].addr; cend = fchunk[c].addr + fchunk[c].len; /* the line below does an address & len match search */ /* unfortunately, I've found that the len fields of */ /* some crc records don't match with the length of */ /* the actual data, so we're not checking right now */ /* if (crcstart-2 >= cstart && crcend <= cend) break; */ /* note the -2 below, it's to make sure the chunk has */ /* space for the CRC value */ if (crcstart - 2 >= cstart && crcstart < cend) break; } if (c >= nfchunks) { printk(KERN_ERR "Failed to find chunk for " "crcrec[%d], addr=0x%06x len=%d , " "aborting crc.\n", i, s3crc[i].addr, s3crc[i].len); return 1; } /* Insert crc */ pr_debug("Adding crc @ 0x%06x\n", s3crc[i].addr - 2); chunkoff = crcstart - cstart - 2; dest = fchunk[c].data + chunkoff; *dest = 0xde; *(dest + 1) = 0xc0; } return result; } /*---------------------------------------------------------------- * free_chunks * * Clears the chunklist data structures in preparation for a new file. * * Arguments: * none * * Returns: * nothing ----------------------------------------------------------------*/ void free_chunks(struct imgchunk *fchunk, unsigned int *nfchunks) { int i; for (i = 0; i < *nfchunks; i++) { kfree(fchunk[i].data); } *nfchunks = 0; memset(fchunk, 0, sizeof(*fchunk)); } /*---------------------------------------------------------------- * free_srecs * * Clears the srec data structures in preparation for a new file. * * Arguments: * none * * Returns: * nothing ----------------------------------------------------------------*/ void free_srecs(void) { ns3data = 0; memset(s3data, 0, sizeof(s3data)); ns3plug = 0; memset(s3plug, 0, sizeof(s3plug)); ns3crc = 0; memset(s3crc, 0, sizeof(s3crc)); ns3info = 0; memset(s3info, 0, sizeof(s3info)); startaddr = 0; } /*---------------------------------------------------------------- * mkimage * * Scans the currently loaded set of S records for data residing * in contiguous memory regions. Each contiguous region is then * made into a 'chunk'. This function assumes that we're building * a new chunk list. Assumes the s3data items are in sorted order. * * Arguments: none * * Returns: * 0 - success * ~0 - failure (probably an errno) ----------------------------------------------------------------*/ int mkimage(struct imgchunk *clist, unsigned int *ccnt) { int result = 0; int i; int j; int currchunk = 0; u32 nextaddr = 0; u32 s3start; u32 s3end; u32 cstart = 0; u32 cend; u32 coffset; /* There may already be data in the chunklist */ *ccnt = 0; /* Establish the location and size of each chunk */ for (i = 0; i < ns3data; i++) { if (s3data[i].addr == nextaddr) { /* existing chunk, grow it */ clist[currchunk].len += s3data[i].len; nextaddr += s3data[i].len; } else { /* New chunk */ (*ccnt)++; currchunk = *ccnt - 1; clist[currchunk].addr = s3data[i].addr; clist[currchunk].len = s3data[i].len; nextaddr = s3data[i].addr + s3data[i].len; /* Expand the chunk if there is a CRC record at */ /* their beginning bound */ for (j = 0; j < ns3crc; j++) { if (s3crc[j].dowrite && s3crc[j].addr == clist[currchunk].addr) { clist[currchunk].addr -= 2; clist[currchunk].len += 2; } } } } /* We're currently assuming there aren't any overlapping chunks */ /* if this proves false, we'll need to add code to coalesce. */ /* Allocate buffer space for chunks */ for (i = 0; i < *ccnt; i++) { clist[i].data = kzalloc(clist[i].len, GFP_KERNEL); if (clist[i].data == NULL) { printk(KERN_ERR "failed to allocate image space, exitting.\n"); return 1; } pr_debug("chunk[%d]: addr=0x%06x len=%d\n", i, clist[i].addr, clist[i].len); } /* Copy srec data to chunks */ for (i = 0; i < ns3data; i++) { s3start = s3data[i].addr; s3end = s3start + s3data[i].len - 1; for (j = 0; j < *ccnt; j++) { cstart = clist[j].addr; cend = cstart + clist[j].len - 1; if (s3start >= cstart && s3end <= cend) break; } if (((unsigned int)j) >= (*ccnt)) { printk(KERN_ERR "s3rec(a=0x%06x,l=%d), no chunk match, exiting.\n", s3start, s3data[i].len); return 1; } coffset = s3start - cstart; memcpy(clist[j].data + coffset, s3data[i].data, s3data[i].len); } return result; } /*---------------------------------------------------------------- * mkpdrlist * * Reads a raw PDA and builds an array of pdrec_t structures. * * Arguments: * pda buffer containing raw PDA bytes * pdrec ptr to an array of pdrec_t's. Will be filled on exit. * nrec ptr to a variable that will contain the count of PDRs * * Returns: * 0 - success * ~0 - failure (probably an errno) ----------------------------------------------------------------*/ int mkpdrlist(struct pda *pda) { int result = 0; u16 *pda16 = (u16 *) pda->buf; int curroff; /* in 'words' */ pda->nrec = 0; curroff = 0; while (curroff < (HFA384x_PDA_LEN_MAX / 2) && le16_to_cpu(pda16[curroff + 1]) != HFA384x_PDR_END_OF_PDA) { pda->rec[pda->nrec] = (hfa384x_pdrec_t *) &(pda16[curroff]); if (le16_to_cpu(pda->rec[pda->nrec]->code) == HFA384x_PDR_NICID) { memcpy(&nicid, &pda->rec[pda->nrec]->data.nicid, sizeof(nicid)); nicid.id = le16_to_cpu(nicid.id); nicid.variant = le16_to_cpu(nicid.variant); nicid.major = le16_to_cpu(nicid.major); nicid.minor = le16_to_cpu(nicid.minor); } if (le16_to_cpu(pda->rec[pda->nrec]->code) == HFA384x_PDR_MFISUPRANGE) { memcpy(&rfid, &pda->rec[pda->nrec]->data.mfisuprange, sizeof(rfid)); rfid.id = le16_to_cpu(rfid.id); rfid.variant = le16_to_cpu(rfid.variant); rfid.bottom = le16_to_cpu(rfid.bottom); rfid.top = le16_to_cpu(rfid.top); } if (le16_to_cpu(pda->rec[pda->nrec]->code) == HFA384x_PDR_CFISUPRANGE) { memcpy(&macid, &pda->rec[pda->nrec]->data.cfisuprange, sizeof(macid)); macid.id = le16_to_cpu(macid.id); macid.variant = le16_to_cpu(macid.variant); macid.bottom = le16_to_cpu(macid.bottom); macid.top = le16_to_cpu(macid.top); } (pda->nrec)++; curroff += le16_to_cpu(pda16[curroff]) + 1; } if (curroff >= (HFA384x_PDA_LEN_MAX / 2)) { printk(KERN_ERR "no end record found or invalid lengths in " "PDR data, exiting. %x %d\n", curroff, pda->nrec); return 1; } if (le16_to_cpu(pda16[curroff + 1]) == HFA384x_PDR_END_OF_PDA) { pda->rec[pda->nrec] = (hfa384x_pdrec_t *) &(pda16[curroff]); (pda->nrec)++; } return result; } /*---------------------------------------------------------------- * plugimage * * Plugs the given image using the given plug records from the given * PDA and filename. * * Arguments: * fchunk Array of image chunks * nfchunks Number of image chunks * s3plug Array of plug records * ns3plug Number of plug records * pda Current pda data * * Returns: * 0 success * ~0 failure ----------------------------------------------------------------*/ int plugimage(struct imgchunk *fchunk, unsigned int nfchunks, struct s3plugrec *s3plug, unsigned int ns3plug, struct pda * pda) { int result = 0; int i; /* plug index */ int j; /* index of PDR or -1 if fname plug */ int c; /* chunk index */ u32 pstart; u32 pend; u32 cstart = 0; u32 cend; u32 chunkoff; u8 *dest; /* for each plug record */ for (i = 0; i < ns3plug; i++) { pstart = s3plug[i].addr; pend = s3plug[i].addr + s3plug[i].len; /* find the matching PDR (or filename) */ if (s3plug[i].itemcode != 0xffffffffUL) { /* not filename */ for (j = 0; j < pda->nrec; j++) { if (s3plug[i].itemcode == le16_to_cpu(pda->rec[j]->code)) break; } } else { j = -1; } if (j >= pda->nrec && j != -1) { /* if no matching PDR, fail */ printk(KERN_WARNING "warning: Failed to find PDR for " "plugrec 0x%04x.\n", s3plug[i].itemcode); continue; /* and move on to the next PDR */ #if 0 /* MSM: They swear that unless it's the MAC address, * the serial number, or the TX calibration records, * then there's reasonable defaults in the f/w * image. Therefore, missing PDRs in the card * should only be a warning, not fatal. * TODO: add fatals for the PDRs mentioned above. */ result = 1; continue; #endif } /* Validate plug len against PDR len */ if (j != -1 && s3plug[i].len < le16_to_cpu(pda->rec[j]->len)) { printk(KERN_ERR "error: Plug vs. PDR len mismatch for " "plugrec 0x%04x, abort plugging.\n", s3plug[i].itemcode); result = 1; continue; } /* Validate plug address against chunk data and identify chunk */ for (c = 0; c < nfchunks; c++) { cstart = fchunk[c].addr; cend = fchunk[c].addr + fchunk[c].len; if (pstart >= cstart && pend <= cend) break; } if (c >= nfchunks) { printk(KERN_ERR "error: Failed to find image chunk for " "plugrec 0x%04x.\n", s3plug[i].itemcode); result = 1; continue; } /* Plug data */ chunkoff = pstart - cstart; dest = fchunk[c].data + chunkoff; pr_debug("Plugging item 0x%04x @ 0x%06x, len=%d, " "cnum=%d coff=0x%06x\n", s3plug[i].itemcode, pstart, s3plug[i].len, c, chunkoff); if (j == -1) { /* plug the filename */ memset(dest, 0, s3plug[i].len); strncpy(dest, PRISM2_USB_FWFILE, s3plug[i].len - 1); } else { /* plug a PDR */ memcpy(dest, &(pda->rec[j]->data), s3plug[i].len); } } return result; } /*---------------------------------------------------------------- * read_cardpda * * Sends the command for the driver to read the pda from the card * named in the device variable. Upon success, the card pda is * stored in the "cardpda" variables. Note that the pda structure * is considered 'well formed' after this function. That means * that the nrecs is valid, the rec array has been set up, and there's * a valid PDAEND record in the raw PDA data. * * Arguments: * pda pda structure * wlandev device * * Returns: * 0 - success * ~0 - failure (probably an errno) ----------------------------------------------------------------*/ int read_cardpda(struct pda *pda, wlandevice_t *wlandev) { int result = 0; struct p80211msg_p2req_readpda msg; /* set up the msg */ msg.msgcode = DIDmsg_p2req_readpda; msg.msglen = sizeof(msg); strcpy(msg.devname, wlandev->name); msg.pda.did = DIDmsg_p2req_readpda_pda; msg.pda.len = HFA384x_PDA_LEN_MAX; msg.pda.status = P80211ENUM_msgitem_status_no_value; msg.resultcode.did = DIDmsg_p2req_readpda_resultcode; msg.resultcode.len = sizeof(u32); msg.resultcode.status = P80211ENUM_msgitem_status_no_value; if (prism2mgmt_readpda(wlandev, &msg) != 0) { /* prism2mgmt_readpda prints an errno if appropriate */ result = -1; } else if (msg.resultcode.data == P80211ENUM_resultcode_success) { memcpy(pda->buf, msg.pda.data, HFA384x_PDA_LEN_MAX); result = mkpdrlist(pda); } else { /* resultcode must've been something other than success */ result = -1; } return result; } /*---------------------------------------------------------------- * read_fwfile * * Reads the given fw file which should have been compiled from an srec * file. Each record in the fw file will either be a plain data record, * a start address record, or other records used for plugging. * * Note that data records are expected to be sorted into * ascending address order in the fw file. * * Note also that the start address record, originally an S7 record in * the srec file, is expected in the fw file to be like a data record but * with a certain address to make it identiable. * * Here's the SREC format that the fw should have come from: * S[37]nnaaaaaaaaddd...dddcc * * nn - number of bytes starting with the address field * aaaaaaaa - address in readable (or big endian) format * dd....dd - 0-245 data bytes (two chars per byte) * cc - checksum * * The S7 record's (there should be only one) address value gets * converted to an S3 record with address of 0xff400000, with the * start address being stored as a 4 byte data word. That address is * the start execution address used for RAM downloads. * * The S3 records have a collection of subformats indicated by the * value of aaaaaaaa: * 0xff000000 - Plug record, data field format: * xxxxxxxxaaaaaaaassssssss * x - PDR code number (little endian) * a - Address in load image to plug (little endian) * s - Length of plug data area (little endian) * * 0xff100000 - CRC16 generation record, data field format: * aaaaaaaassssssssbbbbbbbb * a - Start address for CRC calculation (little endian) * s - Length of data to calculate over (little endian) * b - Boolean, true=write crc, false=don't write * * 0xff200000 - Info record, data field format: * ssssttttdd..dd * s - Size in words (little endian) * t - Info type (little endian), see #defines and * struct s3inforec for details about types. * d - (s - 1) little endian words giving the contents of * the given info type. * * 0xff400000 - Start address record, data field format: * aaaaaaaa * a - Address in load image to plug (little endian) * * Arguments: * record firmware image (ihex record structure) in kernel memory * * Returns: * 0 - success * ~0 - failure (probably an errno) ----------------------------------------------------------------*/ int read_fwfile(const struct ihex_binrec *record) { int i; int rcnt = 0; u16 *tmpinfo; u16 *ptr16; u32 *ptr32, len, addr; pr_debug("Reading fw file ...\n"); while (record) { rcnt++; len = be16_to_cpu(record->len); addr = be32_to_cpu(record->addr); /* Point into data for different word lengths */ ptr32 = (u32 *) record->data; ptr16 = (u16 *) record->data; /* parse what was an S3 srec and put it in the right array */ switch (addr) { case S3ADDR_START: startaddr = *ptr32; pr_debug(" S7 start addr, record=%d " " addr=0x%08x\n", rcnt, startaddr); break; case S3ADDR_PLUG: s3plug[ns3plug].itemcode = *ptr32; s3plug[ns3plug].addr = *(ptr32 + 1); s3plug[ns3plug].len = *(ptr32 + 2); pr_debug(" S3 plugrec, record=%d " "itemcode=0x%08x addr=0x%08x len=%d\n", rcnt, s3plug[ns3plug].itemcode, s3plug[ns3plug].addr, s3plug[ns3plug].len); ns3plug++; if (ns3plug == S3PLUG_MAX) { printk(KERN_ERR "S3 plugrec limit reached - aborting\n"); return 1; } break; case S3ADDR_CRC: s3crc[ns3crc].addr = *ptr32; s3crc[ns3crc].len = *(ptr32 + 1); s3crc[ns3crc].dowrite = *(ptr32 + 2); pr_debug(" S3 crcrec, record=%d " "addr=0x%08x len=%d write=0x%08x\n", rcnt, s3crc[ns3crc].addr, s3crc[ns3crc].len, s3crc[ns3crc].dowrite); ns3crc++; if (ns3crc == S3CRC_MAX) { printk(KERN_ERR "S3 crcrec limit reached - aborting\n"); return 1; } break; case S3ADDR_INFO: s3info[ns3info].len = *ptr16; s3info[ns3info].type = *(ptr16 + 1); pr_debug(" S3 inforec, record=%d " "len=0x%04x type=0x%04x\n", rcnt, s3info[ns3info].len, s3info[ns3info].type); if (((s3info[ns3info].len - 1) * sizeof(u16)) > sizeof(s3info[ns3info].info)) { printk(KERN_ERR " S3 inforec length too long - aborting\n"); return 1; } tmpinfo = (u16 *)&(s3info[ns3info].info.version); pr_debug(" info="); for (i = 0; i < s3info[ns3info].len - 1; i++) { tmpinfo[i] = *(ptr16 + 2 + i); pr_debug("%04x ", tmpinfo[i]); } pr_debug("\n"); ns3info++; if (ns3info == S3INFO_MAX) { printk(KERN_ERR "S3 inforec limit reached - aborting\n"); return 1; } break; default: /* Data record */ s3data[ns3data].addr = addr; s3data[ns3data].len = len; s3data[ns3data].data = (uint8_t *) record->data; ns3data++; if (ns3data == S3DATA_MAX) { printk(KERN_ERR "S3 datarec limit reached - aborting\n"); return 1; } break; } record = ihex_next_binrec(record); } return 0; } /*---------------------------------------------------------------- * writeimage * * Takes the chunks, builds p80211 messages and sends them down * to the driver for writing to the card. * * Arguments: * wlandev device * fchunk Array of image chunks * nfchunks Number of image chunks * * Returns: * 0 success * ~0 failure ----------------------------------------------------------------*/ int writeimage(wlandevice_t *wlandev, struct imgchunk *fchunk, unsigned int nfchunks) { int result = 0; struct p80211msg_p2req_ramdl_state rstatemsg; struct p80211msg_p2req_ramdl_write rwritemsg; struct p80211msg *msgp; u32 resultcode; int i; int j; unsigned int nwrites; u32 curroff; u32 currlen; u32 currdaddr; /* Initialize the messages */ memset(&rstatemsg, 0, sizeof(rstatemsg)); strcpy(rstatemsg.devname, wlandev->name); rstatemsg.msgcode = DIDmsg_p2req_ramdl_state; rstatemsg.msglen = sizeof(rstatemsg); rstatemsg.enable.did = DIDmsg_p2req_ramdl_state_enable; rstatemsg.exeaddr.did = DIDmsg_p2req_ramdl_state_exeaddr; rstatemsg.resultcode.did = DIDmsg_p2req_ramdl_state_resultcode; rstatemsg.enable.status = P80211ENUM_msgitem_status_data_ok; rstatemsg.exeaddr.status = P80211ENUM_msgitem_status_data_ok; rstatemsg.resultcode.status = P80211ENUM_msgitem_status_no_value; rstatemsg.enable.len = sizeof(u32); rstatemsg.exeaddr.len = sizeof(u32); rstatemsg.resultcode.len = sizeof(u32); memset(&rwritemsg, 0, sizeof(rwritemsg)); strcpy(rwritemsg.devname, wlandev->name); rwritemsg.msgcode = DIDmsg_p2req_ramdl_write; rwritemsg.msglen = sizeof(rwritemsg); rwritemsg.addr.did = DIDmsg_p2req_ramdl_write_addr; rwritemsg.len.did = DIDmsg_p2req_ramdl_write_len; rwritemsg.data.did = DIDmsg_p2req_ramdl_write_data; rwritemsg.resultcode.did = DIDmsg_p2req_ramdl_write_resultcode; rwritemsg.addr.status = P80211ENUM_msgitem_status_data_ok; rwritemsg.len.status = P80211ENUM_msgitem_status_data_ok; rwritemsg.data.status = P80211ENUM_msgitem_status_data_ok; rwritemsg.resultcode.status = P80211ENUM_msgitem_status_no_value; rwritemsg.addr.len = sizeof(u32); rwritemsg.len.len = sizeof(u32); rwritemsg.data.len = WRITESIZE_MAX; rwritemsg.resultcode.len = sizeof(u32); /* Send xxx_state(enable) */ pr_debug("Sending dl_state(enable) message.\n"); rstatemsg.enable.data = P80211ENUM_truth_true; rstatemsg.exeaddr.data = startaddr; msgp = (struct p80211msg *) &rstatemsg; result = prism2mgmt_ramdl_state(wlandev, msgp); if (result) { printk(KERN_ERR "writeimage state enable failed w/ result=%d, " "aborting download\n", result); return result; } resultcode = rstatemsg.resultcode.data; if (resultcode != P80211ENUM_resultcode_success) { printk(KERN_ERR "writeimage()->xxxdl_state msg indicates failure, " "w/ resultcode=%d, aborting download.\n", resultcode); return 1; } /* Now, loop through the data chunks and send WRITESIZE_MAX data */ for (i = 0; i < nfchunks; i++) { nwrites = fchunk[i].len / WRITESIZE_MAX; nwrites += (fchunk[i].len % WRITESIZE_MAX) ? 1 : 0; curroff = 0; for (j = 0; j < nwrites; j++) { /* TODO Move this to a separate function */ int lenleft = fchunk[i].len - (WRITESIZE_MAX * j); if (fchunk[i].len > WRITESIZE_MAX) currlen = WRITESIZE_MAX; else currlen = lenleft; curroff = j * WRITESIZE_MAX; currdaddr = fchunk[i].addr + curroff; /* Setup the message */ rwritemsg.addr.data = currdaddr; rwritemsg.len.data = currlen; memcpy(rwritemsg.data.data, fchunk[i].data + curroff, currlen); /* Send flashdl_write(pda) */ pr_debug ("Sending xxxdl_write message addr=%06x len=%d.\n", currdaddr, currlen); msgp = (struct p80211msg *) &rwritemsg; result = prism2mgmt_ramdl_write(wlandev, msgp); /* Check the results */ if (result) { printk(KERN_ERR "writeimage chunk write failed w/ result=%d, " "aborting download\n", result); return result; } resultcode = rstatemsg.resultcode.data; if (resultcode != P80211ENUM_resultcode_success) { printk(KERN_ERR "writeimage()->xxxdl_write msg indicates failure, " "w/ resultcode=%d, aborting download.\n", resultcode); return 1; } } } /* Send xxx_state(disable) */ pr_debug("Sending dl_state(disable) message.\n"); rstatemsg.enable.data = P80211ENUM_truth_false; rstatemsg.exeaddr.data = 0; msgp = (struct p80211msg *) &rstatemsg; result = prism2mgmt_ramdl_state(wlandev, msgp); if (result) { printk(KERN_ERR "writeimage state disable failed w/ result=%d, " "aborting download\n", result); return result; } resultcode = rstatemsg.resultcode.data; if (resultcode != P80211ENUM_resultcode_success) { printk(KERN_ERR "writeimage()->xxxdl_state msg indicates failure, " "w/ resultcode=%d, aborting download.\n", resultcode); return 1; } return result; } int validate_identity(void) { int i; int result = 1; int trump = 0; pr_debug("NIC ID: %#x v%d.%d.%d\n", nicid.id, nicid.major, nicid.minor, nicid.variant); pr_debug("MFI ID: %#x v%d %d->%d\n", rfid.id, rfid.variant, rfid.bottom, rfid.top); pr_debug("CFI ID: %#x v%d %d->%d\n", macid.id, macid.variant, macid.bottom, macid.top); pr_debug("PRI ID: %#x v%d %d->%d\n", priid.id, priid.variant, priid.bottom, priid.top); for (i = 0; i < ns3info; i++) { switch (s3info[i].type) { case 1: pr_debug("Version: ID %#x %d.%d.%d\n", s3info[i].info.version.id, s3info[i].info.version.major, s3info[i].info.version.minor, s3info[i].info.version.variant); break; case 2: pr_debug("Compat: Role %#x Id %#x v%d %d->%d\n", s3info[i].info.compat.role, s3info[i].info.compat.id, s3info[i].info.compat.variant, s3info[i].info.compat.bottom, s3info[i].info.compat.top); /* MAC compat range */ if ((s3info[i].info.compat.role == 1) && (s3info[i].info.compat.id == 2)) { if (s3info[i].info.compat.variant != macid.variant) { result = 2; } } /* PRI compat range */ if ((s3info[i].info.compat.role == 1) && (s3info[i].info.compat.id == 3)) { if ((s3info[i].info.compat.bottom > priid.top) || (s3info[i].info.compat.top < priid.bottom)) { result = 3; } } /* SEC compat range */ if ((s3info[i].info.compat.role == 1) && (s3info[i].info.compat.id == 4)) { /* FIXME: isn't something missing here? */ } break; case 3: pr_debug("Seq: %#x\n", s3info[i].info.buildseq); break; case 4: pr_debug("Platform: ID %#x %d.%d.%d\n", s3info[i].info.version.id, s3info[i].info.version.major, s3info[i].info.version.minor, s3info[i].info.version.variant); if (nicid.id != s3info[i].info.version.id) continue; if (nicid.major != s3info[i].info.version.major) continue; if (nicid.minor != s3info[i].info.version.minor) continue; if ((nicid.variant != s3info[i].info.version.variant) && (nicid.id != 0x8008)) continue; trump = 1; break; case 0x8001: pr_debug("name inforec len %d\n", s3info[i].len); break; default: pr_debug("Unknown inforec type %d\n", s3info[i].type); } } /* walk through */ if (trump && (result != 2)) result = 0; return result; }