/* $OpenBSD: rtwphyio.c,v 1.3 2005/01/19 11:29:27 jsg Exp $ */ /* $NetBSD: rtwphyio.c,v 1.4 2004/12/25 06:58:37 dyoung Exp $ */ /*- * Copyright (c) 2004, 2005 David Young. All rights reserved. * * Programmed for NetBSD by David Young. * * 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. The name of David Young may not be used to endorse or promote * products derived from this software without specific prior * written permission. * * THIS SOFTWARE IS PROVIDED BY David Young ``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 David * Young 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. */ /* * Control input/output with the Philips SA2400 RF front-end and * the baseband processor built into the Realtek RTL8180. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include u_int32_t rtw_grf5101_host_crypt(u_int, u_int32_t); u_int32_t rtw_maxim_swizzle(u_int, uint32_t); u_int32_t rtw_grf5101_mac_crypt(u_int, u_int32_t); void rtw_rf_hostbangbits(struct rtw_regs *, u_int32_t, int, u_int); int rtw_rf_macbangbits(struct rtw_regs *, u_int32_t); const char *rtw_rfchipid_string(enum rtw_rfchipid); static int rtw_macbangbits_timeout = 100; u_int8_t rtw_bbp_read(struct rtw_regs *regs, u_int addr) { KASSERT((addr & ~PRESHIFT(RTW_BB_ADDR_MASK)) == 0); RTW_WRITE(regs, RTW_BB, LSHIFT(addr, RTW_BB_ADDR_MASK) | RTW_BB_RD_MASK | RTW_BB_WR_MASK); delay(10); /* XXX */ RTW_WBR(regs, RTW_BB, RTW_BB); return MASK_AND_RSHIFT(RTW_READ(regs, RTW_BB), RTW_BB_RD_MASK); } int rtw_bbp_write(struct rtw_regs *regs, u_int addr, u_int val) { #define BBP_WRITE_ITERS 50 #define BBP_WRITE_DELAY 1 int i; u_int32_t wrbbp, rdbbp; RTW_DPRINTF(RTW_DEBUG_PHYIO, ("%s: bbp[%u] <- %u\n", __func__, addr, val)); KASSERT((addr & ~PRESHIFT(RTW_BB_ADDR_MASK)) == 0); KASSERT((val & ~PRESHIFT(RTW_BB_WR_MASK)) == 0); wrbbp = LSHIFT(addr, RTW_BB_ADDR_MASK) | RTW_BB_WREN | LSHIFT(val, RTW_BB_WR_MASK) | RTW_BB_RD_MASK, rdbbp = LSHIFT(addr, RTW_BB_ADDR_MASK) | RTW_BB_WR_MASK | RTW_BB_RD_MASK; RTW_DPRINTF(RTW_DEBUG_PHYIO, ("%s: rdbbp = %#08x, wrbbp = %#08x\n", __func__, rdbbp, wrbbp)); for (i = BBP_WRITE_ITERS; --i >= 0; ) { RTW_RBW(regs, RTW_BB, RTW_BB); RTW_WRITE(regs, RTW_BB, wrbbp); RTW_SYNC(regs, RTW_BB, RTW_BB); RTW_WRITE(regs, RTW_BB, rdbbp); RTW_SYNC(regs, RTW_BB, RTW_BB); delay(BBP_WRITE_DELAY); /* 1 microsecond */ if (MASK_AND_RSHIFT(RTW_READ(regs, RTW_BB), RTW_BB_RD_MASK) == val) { RTW_DPRINTF(RTW_DEBUG_PHYIO, ("%s: finished in %dus\n", __func__, BBP_WRITE_DELAY * (BBP_WRITE_ITERS - i))); return 0; } delay(BBP_WRITE_DELAY); /* again */ } printf("%s: timeout\n", __func__); return -1; } /* Help rtw_rf_hostwrite bang bits to RF over 3-wire interface. */ void rtw_rf_hostbangbits(struct rtw_regs *regs, u_int32_t bits, int lo_to_hi, u_int nbits) { int i; u_int32_t mask, reg; KASSERT(nbits <= 32); RTW_DPRINTF(RTW_DEBUG_PHYIO, ("%s: %u bits, %#08x, %s\n", __func__, nbits, bits, (lo_to_hi) ? "lo to hi" : "hi to lo")); reg = RTW_PHYCFG_HST; RTW_WRITE(regs, RTW_PHYCFG, reg); RTW_SYNC(regs, RTW_PHYCFG, RTW_PHYCFG); if (lo_to_hi) mask = 0x1; else mask = 1 << (nbits - 1); for (i = 0; i < nbits; i++) { RTW_DPRINTF(RTW_DEBUG_PHYBITIO, ("%s: bits %#08x mask %#08x -> bit %#08x\n", __func__, bits, mask, bits & mask)); if ((bits & mask) != 0) reg |= RTW_PHYCFG_HST_DATA; else reg &= ~RTW_PHYCFG_HST_DATA; reg |= RTW_PHYCFG_HST_CLK; RTW_WRITE(regs, RTW_PHYCFG, reg); RTW_SYNC(regs, RTW_PHYCFG, RTW_PHYCFG); DELAY(2); /* arbitrary delay */ reg &= ~RTW_PHYCFG_HST_CLK; RTW_WRITE(regs, RTW_PHYCFG, reg); RTW_SYNC(regs, RTW_PHYCFG, RTW_PHYCFG); if (lo_to_hi) mask <<= 1; else mask >>= 1; } reg |= RTW_PHYCFG_HST_EN; KASSERT((reg & RTW_PHYCFG_HST_CLK) == 0); RTW_WRITE(regs, RTW_PHYCFG, reg); RTW_SYNC(regs, RTW_PHYCFG, RTW_PHYCFG); } /* Help rtw_rf_macwrite: tell MAC to bang bits to RF over the 3-wire * interface. */ int rtw_rf_macbangbits(struct rtw_regs *regs, u_int32_t reg) { int i; RTW_DPRINTF(RTW_DEBUG_PHY, ("%s: %#08x\n", __func__, reg)); RTW_WRITE(regs, RTW_PHYCFG, RTW_PHYCFG_MAC_POLL | reg); RTW_WBR(regs, RTW_PHYCFG, RTW_PHYCFG); for (i = rtw_macbangbits_timeout; --i >= 0; delay(1)) { if ((RTW_READ(regs, RTW_PHYCFG) & RTW_PHYCFG_MAC_POLL) == 0) { RTW_DPRINTF(RTW_DEBUG_PHY, ("%s: finished in %dus\n", __func__, rtw_macbangbits_timeout - i)); return 0; } RTW_RBR(regs, RTW_PHYCFG, RTW_PHYCFG); /* XXX paranoia? */ } printf("%s: RTW_PHYCFG_MAC_POLL still set.\n", __func__); return -1; } u_int32_t rtw_grf5101_host_crypt(u_int addr, u_int32_t val) { /* TBD */ return 0; } u_int32_t rtw_grf5101_mac_crypt(u_int addr, u_int32_t val) { u_int32_t data_and_addr; #define EXTRACT_NIBBLE(d, which) (((d) >> (4 * (which))) & 0xf) static u_int8_t caesar[16] = {0x0, 0x8, 0x4, 0xc, 0x2, 0xa, 0x6, 0xe, 0x1, 0x9, 0x5, 0xd, 0x3, 0xb, 0x7, 0xf}; data_and_addr = caesar[EXTRACT_NIBBLE(val, 2)] | (caesar[EXTRACT_NIBBLE(val, 1)] << 4) | (caesar[EXTRACT_NIBBLE(val, 0)] << 8) | (caesar[(addr >> 1) & 0xf] << 12) | ((addr & 0x1) << 16) | (caesar[EXTRACT_NIBBLE(val, 3)] << 24); return LSHIFT(data_and_addr, RTW_PHYCFG_MAC_PHILIPS_ADDR_MASK|RTW_PHYCFG_MAC_PHILIPS_DATA_MASK); #undef EXTRACT_NIBBLE } const char * rtw_rfchipid_string(enum rtw_rfchipid rfchipid) { switch (rfchipid) { case RTW_RFCHIPID_MAXIM: return "Maxim"; case RTW_RFCHIPID_PHILIPS: return "Philips"; case RTW_RFCHIPID_GCT: return "GCT"; case RTW_RFCHIPID_RFMD: return "RFMD"; case RTW_RFCHIPID_INTERSIL: return "Intersil"; default: return "unknown"; } } /* Bang bits over the 3-wire interface. */ int rtw_rf_hostwrite(struct rtw_regs *regs, enum rtw_rfchipid rfchipid, u_int addr, u_int32_t val) { u_int nbits; int lo_to_hi; u_int32_t bits; RTW_DPRINTF(RTW_DEBUG_PHYIO, ("%s: %s[%u] <- %#08x\n", __func__, rtw_rfchipid_string(rfchipid), addr, val)); switch (rfchipid) { case RTW_RFCHIPID_MAXIM: nbits = 16; lo_to_hi = 0; bits = LSHIFT(val, MAX2820_TWI_DATA_MASK) | LSHIFT(addr, MAX2820_TWI_ADDR_MASK); break; case RTW_RFCHIPID_PHILIPS: KASSERT((addr & ~PRESHIFT(SA2400_TWI_ADDR_MASK)) == 0); KASSERT((val & ~PRESHIFT(SA2400_TWI_DATA_MASK)) == 0); bits = LSHIFT(val, SA2400_TWI_DATA_MASK) | LSHIFT(addr, SA2400_TWI_ADDR_MASK) | SA2400_TWI_WREN; nbits = 32; lo_to_hi = 1; break; case RTW_RFCHIPID_GCT: case RTW_RFCHIPID_RFMD: KASSERT((addr & ~PRESHIFT(SI4126_TWI_ADDR_MASK)) == 0); KASSERT((val & ~PRESHIFT(SI4126_TWI_DATA_MASK)) == 0); if (rfchipid == RTW_RFCHIPID_GCT) bits = rtw_grf5101_host_crypt(addr, val); else { bits = LSHIFT(val, SI4126_TWI_DATA_MASK) | LSHIFT(addr, SI4126_TWI_ADDR_MASK); } nbits = 22; lo_to_hi = 0; break; case RTW_RFCHIPID_INTERSIL: default: printf("%s: unknown rfchipid %d\n", __func__, rfchipid); return -1; } rtw_rf_hostbangbits(regs, bits, lo_to_hi, nbits); return 0; } u_int32_t rtw_maxim_swizzle(u_int addr, u_int32_t val) { u_int32_t hidata, lodata; KASSERT((val & ~(RTW_MAXIM_LODATA_MASK|RTW_MAXIM_HIDATA_MASK)) == 0); lodata = MASK_AND_RSHIFT(val, RTW_MAXIM_LODATA_MASK); hidata = MASK_AND_RSHIFT(val, RTW_MAXIM_HIDATA_MASK); return LSHIFT(lodata, RTW_PHYCFG_MAC_MAXIM_LODATA_MASK) | LSHIFT(hidata, RTW_PHYCFG_MAC_MAXIM_HIDATA_MASK) | LSHIFT(addr, RTW_PHYCFG_MAC_MAXIM_ADDR_MASK); } /* Tell the MAC what to bang over the 3-wire interface. */ int rtw_rf_macwrite(struct rtw_regs *regs, enum rtw_rfchipid rfchipid, u_int addr, u_int32_t val) { u_int32_t reg; RTW_DPRINTF(RTW_DEBUG_PHYIO, ("%s: %s[%u] <- %#08x\n", __func__, rtw_rfchipid_string(rfchipid), addr, val)); switch (rfchipid) { case RTW_RFCHIPID_GCT: reg = rtw_grf5101_mac_crypt(addr, val); break; case RTW_RFCHIPID_MAXIM: reg = rtw_maxim_swizzle(addr, val); break; default: /* XXX */ case RTW_RFCHIPID_PHILIPS: KASSERT( (addr & ~PRESHIFT(RTW_PHYCFG_MAC_PHILIPS_ADDR_MASK)) == 0); KASSERT( (val & ~PRESHIFT(RTW_PHYCFG_MAC_PHILIPS_DATA_MASK)) == 0); reg = LSHIFT(addr, RTW_PHYCFG_MAC_PHILIPS_ADDR_MASK) | LSHIFT(val, RTW_PHYCFG_MAC_PHILIPS_DATA_MASK); } switch (rfchipid) { case RTW_RFCHIPID_GCT: case RTW_RFCHIPID_MAXIM: case RTW_RFCHIPID_RFMD: reg |= RTW_PHYCFG_MAC_RFTYPE_RFMD; break; case RTW_RFCHIPID_INTERSIL: reg |= RTW_PHYCFG_MAC_RFTYPE_INTERSIL; break; case RTW_RFCHIPID_PHILIPS: reg |= RTW_PHYCFG_MAC_RFTYPE_PHILIPS; break; default: printf("%s: unknown rfchipid %d\n", __func__, rfchipid); return -1; } return rtw_rf_macbangbits(regs, reg); }