/* * General Purpose functions for the global management of the * 8260 Communication Processor Module. * Copyright (c) 1999-2001 Dan Malek * Copyright (c) 2000 MontaVista Software, Inc (source@mvista.com) * 2.3.99 Updates * * 2006 (c) MontaVista Software, Inc. * Vitaly Bordug * Merged to arch/powerpc from arch/ppc/syslib/cpm2_common.c * * This file is licensed under the terms of the GNU General Public License * version 2. This program is licensed "as is" without any warranty of any * kind, whether express or implied. */ /* * * In addition to the individual control of the communication * channels, there are a few functions that globally affect the * communication processor. * * Buffer descriptors must be allocated from the dual ported memory * space. The allocator for that is here. When the communication * process is reset, we reclaim the memory available. There is * currently no deallocator for this memory. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include cpm_cpm2_t __iomem *cpmp; /* Pointer to comm processor space */ /* We allocate this here because it is used almost exclusively for * the communication processor devices. */ cpm2_map_t __iomem *cpm2_immr; #define CPM_MAP_SIZE (0x40000) /* 256k - the PQ3 reserve this amount of space for CPM as it is larger than on PQ2 */ void __init cpm2_reset(void) { #ifdef CONFIG_PPC_85xx cpm2_immr = ioremap(CPM_MAP_ADDR, CPM_MAP_SIZE); #else cpm2_immr = ioremap(get_immrbase(), CPM_MAP_SIZE); #endif /* Reclaim the DP memory for our use. */ cpm_muram_init(); /* Tell everyone where the comm processor resides. */ cpmp = &cpm2_immr->im_cpm; #ifndef CONFIG_PPC_EARLY_DEBUG_CPM /* Reset the CPM. */ cpm_command(CPM_CR_RST, 0); #endif } static DEFINE_SPINLOCK(cmd_lock); #define MAX_CR_CMD_LOOPS 10000 int cpm_command(u32 command, u8 opcode) { int i, ret; unsigned long flags; spin_lock_irqsave(&cmd_lock, flags); ret = 0; out_be32(&cpmp->cp_cpcr, command | opcode | CPM_CR_FLG); for (i = 0; i < MAX_CR_CMD_LOOPS; i++) if ((in_be32(&cpmp->cp_cpcr) & CPM_CR_FLG) == 0) goto out; printk(KERN_ERR "%s(): Not able to issue CPM command\n", __func__); ret = -EIO; out: spin_unlock_irqrestore(&cmd_lock, flags); return ret; } EXPORT_SYMBOL(cpm_command); /* Set a baud rate generator. This needs lots of work. There are * eight BRGs, which can be connected to the CPM channels or output * as clocks. The BRGs are in two different block of internal * memory mapped space. * The baud rate clock is the system clock divided by something. * It was set up long ago during the initial boot phase and is * is given to us. * Baud rate clocks are zero-based in the driver code (as that maps * to port numbers). Documentation uses 1-based numbering. */ #define BRG_INT_CLK (get_brgfreq()) #define BRG_UART_CLK (BRG_INT_CLK/16) /* This function is used by UARTS, or anything else that uses a 16x * oversampled clock. */ void cpm_setbrg(uint brg, uint rate) { u32 __iomem *bp; /* This is good enough to get SMCs running..... */ if (brg < 4) { bp = cpm2_map_size(im_brgc1, 16); } else { bp = cpm2_map_size(im_brgc5, 16); brg -= 4; } bp += brg; out_be32(bp, (((BRG_UART_CLK / rate) - 1) << 1) | CPM_BRG_EN); cpm2_unmap(bp); } /* This function is used to set high speed synchronous baud rate * clocks. */ void cpm2_fastbrg(uint brg, uint rate, int div16) { u32 __iomem *bp; u32 val; if (brg < 4) { bp = cpm2_map_size(im_brgc1, 16); } else { bp = cpm2_map_size(im_brgc5, 16); brg -= 4; } bp += brg; val = ((BRG_INT_CLK / rate) << 1) | CPM_BRG_EN; if (div16) val |= CPM_BRG_DIV16; out_be32(bp, val); cpm2_unmap(bp); } int cpm2_clk_setup(enum cpm_clk_target target, int clock, int mode) { int ret = 0; int shift; int i, bits = 0; cpmux_t __iomem *im_cpmux; u32 __iomem *reg; u32 mask = 7; u8 clk_map[][3] = { {CPM_CLK_FCC1, CPM_BRG5, 0}, {CPM_CLK_FCC1, CPM_BRG6, 1}, {CPM_CLK_FCC1, CPM_BRG7, 2}, {CPM_CLK_FCC1, CPM_BRG8, 3}, {CPM_CLK_FCC1, CPM_CLK9, 4}, {CPM_CLK_FCC1, CPM_CLK10, 5}, {CPM_CLK_FCC1, CPM_CLK11, 6}, {CPM_CLK_FCC1, CPM_CLK12, 7}, {CPM_CLK_FCC2, CPM_BRG5, 0}, {CPM_CLK_FCC2, CPM_BRG6, 1}, {CPM_CLK_FCC2, CPM_BRG7, 2}, {CPM_CLK_FCC2, CPM_BRG8, 3}, {CPM_CLK_FCC2, CPM_CLK13, 4}, {CPM_CLK_FCC2, CPM_CLK14, 5}, {CPM_CLK_FCC2, CPM_CLK15, 6}, {CPM_CLK_FCC2, CPM_CLK16, 7}, {CPM_CLK_FCC3, CPM_BRG5, 0}, {CPM_CLK_FCC3, CPM_BRG6, 1}, {CPM_CLK_FCC3, CPM_BRG7, 2}, {CPM_CLK_FCC3, CPM_BRG8, 3}, {CPM_CLK_FCC3, CPM_CLK13, 4}, {CPM_CLK_FCC3, CPM_CLK14, 5}, {CPM_CLK_FCC3, CPM_CLK15, 6}, {CPM_CLK_FCC3, CPM_CLK16, 7}, {CPM_CLK_SCC1, CPM_BRG1, 0}, {CPM_CLK_SCC1, CPM_BRG2, 1}, {CPM_CLK_SCC1, CPM_BRG3, 2}, {CPM_CLK_SCC1, CPM_BRG4, 3}, {CPM_CLK_SCC1, CPM_CLK11, 4}, {CPM_CLK_SCC1, CPM_CLK12, 5}, {CPM_CLK_SCC1, CPM_CLK3, 6}, {CPM_CLK_SCC1, CPM_CLK4, 7}, {CPM_CLK_SCC2, CPM_BRG1, 0}, {CPM_CLK_SCC2, CPM_BRG2, 1}, {CPM_CLK_SCC2, CPM_BRG3, 2}, {CPM_CLK_SCC2, CPM_BRG4, 3}, {CPM_CLK_SCC2, CPM_CLK11, 4}, {CPM_CLK_SCC2, CPM_CLK12, 5}, {CPM_CLK_SCC2, CPM_CLK3, 6}, {CPM_CLK_SCC2, CPM_CLK4, 7}, {CPM_CLK_SCC3, CPM_BRG1, 0}, {CPM_CLK_SCC3, CPM_BRG2, 1}, {CPM_CLK_SCC3, CPM_BRG3, 2}, {CPM_CLK_SCC3, CPM_BRG4, 3}, {CPM_CLK_SCC3, CPM_CLK5, 4}, {CPM_CLK_SCC3, CPM_CLK6, 5}, {CPM_CLK_SCC3, CPM_CLK7, 6}, {CPM_CLK_SCC3, CPM_CLK8, 7}, {CPM_CLK_SCC4, CPM_BRG1, 0}, {CPM_CLK_SCC4, CPM_BRG2, 1}, {CPM_CLK_SCC4, CPM_BRG3, 2}, {CPM_CLK_SCC4, CPM_BRG4, 3}, {CPM_CLK_SCC4, CPM_CLK5, 4}, {CPM_CLK_SCC4, CPM_CLK6, 5}, {CPM_CLK_SCC4, CPM_CLK7, 6}, {CPM_CLK_SCC4, CPM_CLK8, 7}, }; im_cpmux = cpm2_map(im_cpmux); switch (target) { case CPM_CLK_SCC1: reg = &im_cpmux->cmx_scr; shift = 24; break; case CPM_CLK_SCC2: reg = &im_cpmux->cmx_scr; shift = 16; break; case CPM_CLK_SCC3: reg = &im_cpmux->cmx_scr; shift = 8; break; case CPM_CLK_SCC4: reg = &im_cpmux->cmx_scr; shift = 0; break; case CPM_CLK_FCC1: reg = &im_cpmux->cmx_fcr; shift = 24; break; case CPM_CLK_FCC2: reg = &im_cpmux->cmx_fcr; shift = 16; break; case CPM_CLK_FCC3: reg = &im_cpmux->cmx_fcr; shift = 8; break; default: printk(KERN_ERR "cpm2_clock_setup: invalid clock target\n"); return -EINVAL; } if (mode == CPM_CLK_RX) shift += 3; for (i = 0; i < ARRAY_SIZE(clk_map); i++) { if (clk_map[i][0] == target && clk_map[i][1] == clock) { bits = clk_map[i][2]; break; } } if (i == ARRAY_SIZE(clk_map)) ret = -EINVAL; bits <<= shift; mask <<= shift; out_be32(reg, (in_be32(reg) & ~mask) | bits); cpm2_unmap(im_cpmux); return ret; } int cpm2_smc_clk_setup(enum cpm_clk_target target, int clock) { int ret = 0; int shift; int i, bits = 0; cpmux_t __iomem *im_cpmux; u8 __iomem *reg; u8 mask = 3; u8 clk_map[][3] = { {CPM_CLK_SMC1, CPM_BRG1, 0}, {CPM_CLK_SMC1, CPM_BRG7, 1}, {CPM_CLK_SMC1, CPM_CLK7, 2}, {CPM_CLK_SMC1, CPM_CLK9, 3}, {CPM_CLK_SMC2, CPM_BRG2, 0}, {CPM_CLK_SMC2, CPM_BRG8, 1}, {CPM_CLK_SMC2, CPM_CLK4, 2}, {CPM_CLK_SMC2, CPM_CLK15, 3}, }; im_cpmux = cpm2_map(im_cpmux); switch (target) { case CPM_CLK_SMC1: reg = &im_cpmux->cmx_smr; mask = 3; shift = 4; break; case CPM_CLK_SMC2: reg = &im_cpmux->cmx_smr; mask = 3; shift = 0; break; default: printk(KERN_ERR "cpm2_smc_clock_setup: invalid clock target\n"); return -EINVAL; } for (i = 0; i < ARRAY_SIZE(clk_map); i++) { if (clk_map[i][0] == target && clk_map[i][1] == clock) { bits = clk_map[i][2]; break; } } if (i == ARRAY_SIZE(clk_map)) ret = -EINVAL; bits <<= shift; mask <<= shift; out_8(reg, (in_8(reg) & ~mask) | bits); cpm2_unmap(im_cpmux); return ret; } struct cpm2_ioports { u32 dir, par, sor, odr, dat; u32 res[3]; }; void cpm2_set_pin(int port, int pin, int flags) { struct cpm2_ioports __iomem *iop = (struct cpm2_ioports __iomem *)&cpm2_immr->im_ioport; pin = 1 << (31 - pin); if (flags & CPM_PIN_OUTPUT) setbits32(&iop[port].dir, pin); else clrbits32(&iop[port].dir, pin); if (!(flags & CPM_PIN_GPIO)) setbits32(&iop[port].par, pin); else clrbits32(&iop[port].par, pin); if (flags & CPM_PIN_SECONDARY) setbits32(&iop[port].sor, pin); else clrbits32(&iop[port].sor, pin); if (flags & CPM_PIN_OPENDRAIN) setbits32(&iop[port].odr, pin); else clrbits32(&iop[port].odr, pin); }