From: Martyn Welch Currently this code doesn't compile, so it is disabled. That should be fixed up... Signed-off-by: Martyn Welch Signed-off-by: Greg Kroah-Hartman --- drivers/staging/vme/Kconfig | 2 drivers/staging/vme/Makefile | 2 drivers/staging/vme/bridges/Kconfig | 8 drivers/staging/vme/bridges/Makefile | 1 drivers/staging/vme/bridges/vme_ca91cx42.c | 1811 +++++++++++++++++++++++++++++ drivers/staging/vme/bridges/vme_ca91cx42.h | 403 ++++++ 6 files changed, 2225 insertions(+), 2 deletions(-) --- /dev/null +++ b/drivers/staging/vme/bridges/Kconfig @@ -0,0 +1,8 @@ +comment "VME Bridge Drivers" + +config VME_CA91CX42 + tristate "Universe I/II" + depends on BROKEN + help + If you say Y here you get support for the Tundra CA91C042 (Universe I) + and CA91C142 (Universe II) VME bridge chips. --- /dev/null +++ b/drivers/staging/vme/bridges/Makefile @@ -0,0 +1 @@ +obj-$(CONFIG_VME_CA91CX42) += vme_ca91cx42.o --- /dev/null +++ b/drivers/staging/vme/bridges/vme_ca91cx42.c @@ -0,0 +1,1811 @@ +/* + * Support for the Tundra Universe I/II VME-PCI Bridge Chips + * + * Author: Martyn Welch + * Copyright 2008 GE Fanuc Intelligent Platforms Embedded Systems, Inc. + * + * Based on work by Tom Armistead and Ajit Prem + * Copyright 2004 Motorola Inc. + * + * Derived from ca91c042.c by Michael Wyrick + * + * This program is free software; you can redistribute it and/or modify it + * under the terms of the GNU General Public License as published by the + * Free Software Foundation; either version 2 of the License, or (at your + * option) any later version. + */ + +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include +#include + +#include "../vme.h" +#include "../vme_bridge.h" +#include "vme_ca91cx42.h" + +extern struct vmeSharedData *vmechip_interboard_data; +extern dma_addr_t vmechip_interboard_datap; +extern const int vmechip_revision; +extern const int vmechip_devid; +extern const int vmechip_irq; +extern int vmechip_irq_overhead_ticks; +extern char *vmechip_baseaddr; +extern const int vme_slotnum; +extern int vme_syscon; +extern unsigned int out_image_va[]; +extern unsigned int vme_irqlog[8][0x100]; + +static int outCTL[] = { LSI0_CTL, LSI1_CTL, LSI2_CTL, LSI3_CTL, + LSI4_CTL, LSI5_CTL, LSI6_CTL, LSI7_CTL +}; + +static int outBS[] = { LSI0_BS, LSI1_BS, LSI2_BS, LSI3_BS, + LSI4_BS, LSI5_BS, LSI6_BS, LSI7_BS +}; + +static int outBD[] = { LSI0_BD, LSI1_BD, LSI2_BD, LSI3_BD, + LSI4_BD, LSI5_BD, LSI6_BD, LSI7_BD +}; + +static int outTO[] = { LSI0_TO, LSI1_TO, LSI2_TO, LSI3_TO, + LSI4_TO, LSI5_TO, LSI6_TO, LSI7_TO +}; + +static int inCTL[] = { VSI0_CTL, VSI1_CTL, VSI2_CTL, VSI3_CTL, + VSI4_CTL, VSI5_CTL, VSI6_CTL, VSI7_CTL +}; + +static int inBS[] = { VSI0_BS, VSI1_BS, VSI2_BS, VSI3_BS, + VSI4_BS, VSI5_BS, VSI6_BS, VSI7_BS +}; + +static int inBD[] = { VSI0_BD, VSI1_BD, VSI2_BD, VSI3_BD, + VSI4_BD, VSI5_BD, VSI6_BD, VSI7_BD +}; + +static int inTO[] = { VSI0_TO, VSI1_TO, VSI2_TO, VSI3_TO, + VSI4_TO, VSI5_TO, VSI6_TO, VSI7_TO +}; +static int vmevec[7] = { V1_STATID, V2_STATID, V3_STATID, V4_STATID, + V5_STATID, V6_STATID, V7_STATID +}; + +struct interrupt_counters { + unsigned int acfail; + unsigned int sysfail; + unsigned int sw_int; + unsigned int sw_iack; + unsigned int verr; + unsigned int lerr; + unsigned int lm; + unsigned int mbox; + unsigned int dma; + unsigned int virq[7]; + unsigned int vown; +}; + +extern wait_queue_head_t dma_queue[]; +extern wait_queue_head_t lm_queue; +extern wait_queue_head_t mbox_queue; + +extern int tb_speed; + +unsigned int uni_irq_time; +unsigned int uni_dma_irq_time; +unsigned int uni_lm_event; + +static spinlock_t lm_lock = SPIN_LOCK_UNLOCKED; + +static struct interrupt_counters Interrupt_counters = { 0, 0, + 0, 0, 0, 0, + 0, 0, 0, + {0, 0, 0, 0, 0, 0, 0}, + 0 +}; + +#define read_register(offset) readl(vmechip_baseaddr + offset) +#define write_register(value,offset) writel(value, vmechip_baseaddr + offset) +#define read_register_word(offset) readw(vmechip_baseaddr + offset) +#define write_register_word(value,offset) writew(value, vmechip_baseaddr + offset) + +int uni_procinfo(char *buf) +{ + char *p; + + p = buf; + + p += sprintf(p, "\n"); + { + unsigned long misc_ctl; + + misc_ctl = read_register(MISC_CTL); + p += sprintf(p, "MISC_CTL:\t\t\t0x%08lx\n", misc_ctl); + p += sprintf(p, "VME Bus Time Out:\t\t"); + switch ((misc_ctl & UNIV_BM_MISC_CTL_VBTO) >> + UNIV_OF_MISC_CTL_VBTO) { + case 0x0: + p += sprintf(p, "Disabled\n"); + break; + case 0x1: + p += sprintf(p, "16 us\n"); + break; + case 0x2: + p += sprintf(p, "32 us\n"); + break; + case 0x3: + p += sprintf(p, "64 us\n"); + break; + case 0x4: + p += sprintf(p, "128 us\n"); + break; + case 0x5: + p += sprintf(p, "256 us\n"); + break; + case 0x6: + p += sprintf(p, "512 us\n"); + break; + case 0x7: + p += sprintf(p, "1024 us\n"); + break; + default: + p += sprintf(p, "Reserved Value, Undefined\n"); + } + p += sprintf(p, "VME Arbitration Time Out:\t"); + switch ((misc_ctl & UNIV_BM_MISC_CTL_VARBTO) >> + UNIV_OF_MISC_CTL_VARBTO) { + case 0x0: + p += sprintf(p, "Disabled"); + break; + case 0x1: + p += sprintf(p, "16 us"); + break; + case 0x2: + p += sprintf(p, "256 us"); + break; + default: + p += sprintf(p, "Reserved Value, Undefined"); + } + if (misc_ctl & UNIV_BM_MISC_CTL_VARB) + p += sprintf(p, ", Priority Arbitration\n"); + else + p += sprintf(p, ", Round Robin Arbitration\n"); + p += sprintf(p, "\n"); + } + + { + unsigned int lmisc; + unsigned int crt; + unsigned int cwt; + + lmisc = read_register(LMISC); + p += sprintf(p, "LMISC:\t\t\t\t0x%08x\n", lmisc); + crt = (lmisc & UNIV_BM_LMISC_CRT) >> UNIV_OF_LMISC_CRT; + cwt = (lmisc & UNIV_BM_LMISC_CWT) >> UNIV_OF_LMISC_CWT; + p += sprintf(p, "Coupled Request Timer:\t\t"); + switch (crt) { + case 0x0: + p += sprintf(p, "Disabled\n"); + break; + case 0x1: + p += sprintf(p, "128 us\n"); + break; + case 0x2: + p += sprintf(p, "256 us\n"); + break; + case 0x3: + p += sprintf(p, "512 us\n"); + break; + case 0x4: + p += sprintf(p, "1024 us\n"); + break; + case 0x5: + p += sprintf(p, "2048 us\n"); + break; + case 0x6: + p += sprintf(p, "4096 us\n"); + break; + default: + p += sprintf(p, "Reserved\n"); + } + p += sprintf(p, "Coupled Window Timer:\t\t"); + switch (cwt) { + case 0x0: + p += sprintf(p, "Disabled\n"); + break; + case 0x1: + p += sprintf(p, "16 PCI Clocks\n"); + break; + case 0x2: + p += sprintf(p, "32 PCI Clocks\n"); + break; + case 0x3: + p += sprintf(p, "64 PCI Clocks\n"); + break; + case 0x4: + p += sprintf(p, "128 PCI Clocks\n"); + break; + case 0x5: + p += sprintf(p, "256 PCI Clocks\n"); + break; + case 0x6: + p += sprintf(p, "512 PCI Clocks\n"); + break; + default: + p += sprintf(p, "Reserved\n"); + } + p += sprintf(p, "\n"); + } + { + unsigned int mast_ctl; + + mast_ctl = read_register(MAST_CTL); + p += sprintf(p, "MAST_CTL:\t\t\t0x%08x\n", mast_ctl); + { + int retries; + + retries = ((mast_ctl & UNIV_BM_MAST_CTL_MAXRTRY) + >> UNIV_OF_MAST_CTL_MAXRTRY) * 64; + p += sprintf(p, "Max PCI Master Retries:\t\t"); + if (retries) + p += sprintf(p, "%d\n", retries); + else + p += sprintf(p, "Forever\n"); + } + + p += sprintf(p, "Posted Write Transfer Count:\t"); + switch ((mast_ctl & UNIV_BM_MAST_CTL_PWON) >> + UNIV_OF_MAST_CTL_PWON) { + case 0x0: + p += sprintf(p, "128 Bytes\n"); + break; + case 0x1: + p += sprintf(p, "256 Bytes\n"); + break; + case 0x2: + p += sprintf(p, "512 Bytes\n"); + break; + case 0x3: + p += sprintf(p, "1024 Bytes\n"); + break; + case 0x4: + p += sprintf(p, "2048 Bytes\n"); + break; + case 0x5: + p += sprintf(p, "4096 Bytes\n"); + break; + default: + p += sprintf(p, "Undefined\n"); + } + + p += sprintf(p, "VMEbus Request Level:\t\t"); + switch ((mast_ctl & UNIV_BM_MAST_CTL_VRL) >> + UNIV_OF_MAST_CTL_VRL) { + case 0x0: + p += sprintf(p, "Level 0\n"); + case 0x1: + p += sprintf(p, "Level 1\n"); + case 0x2: + p += sprintf(p, "Level 2\n"); + case 0x3: + p += sprintf(p, "Level 3\n"); + } + p += sprintf(p, "VMEbus Request Mode:\t\t"); + if (mast_ctl & UNIV_BM_MAST_CTL_VRM) + p += sprintf(p, "Fair Request Mode\n"); + else + p += sprintf(p, "Demand Request Mode\n"); + p += sprintf(p, "VMEbus Release Mode:\t\t"); + if (mast_ctl & UNIV_BM_MAST_CTL_VREL) + p += sprintf(p, "Release on Request\n"); + else + p += sprintf(p, "Release when Done\n"); + p += sprintf(p, "VMEbus Ownership Bit:\t\t"); + if (mast_ctl & UNIV_BM_MAST_CTL_VOWN) + p += sprintf(p, "Acquire and hold VMEbus\n"); + else + p += sprintf(p, "Release VMEbus\n"); + p += sprintf(p, "VMEbus Ownership Bit Ack:\t"); + if (mast_ctl & UNIV_BM_MAST_CTL_VOWN_ACK) + p += sprintf(p, "Owning VMEbus\n"); + else + p += sprintf(p, "Not Owning VMEbus\n"); + p += sprintf(p, "\n"); + } + { + unsigned int misc_stat; + + misc_stat = read_register(MISC_STAT); + p += sprintf(p, "MISC_STAT:\t\t\t0x%08x\n", misc_stat); + p += sprintf(p, "Universe BBSY:\t\t\t"); + if (misc_stat & UNIV_BM_MISC_STAT_MYBBSY) + p += sprintf(p, "Negated\n"); + else + p += sprintf(p, "Asserted\n"); + p += sprintf(p, "Transmit FIFO:\t\t\t"); + if (misc_stat & UNIV_BM_MISC_STAT_TXFE) + p += sprintf(p, "Empty\n"); + else + p += sprintf(p, "Not empty\n"); + p += sprintf(p, "Receive FIFO:\t\t\t"); + if (misc_stat & UNIV_BM_MISC_STAT_RXFE) + p += sprintf(p, "Empty\n"); + else + p += sprintf(p, "Not Empty\n"); + p += sprintf(p, "\n"); + } + + p += sprintf(p, "Latency Timer:\t\t\t%02d Clocks\n\n", + (read_register(UNIV_PCI_MISC0) & + UNIV_BM_PCI_MISC0_LTIMER) >> UNIV_OF_PCI_MISC0_LTIMER); + + { + unsigned int lint_en; + unsigned int lint_stat; + + lint_en = read_register(LINT_EN); + lint_stat = read_register(LINT_STAT); + +#define REPORT_IRQ(name,field) \ + p += sprintf(p, (lint_en & UNIV_BM_LINT_##name) ? "Enabled" : "Masked"); \ + p += sprintf(p, ", triggered %d times", Interrupt_counters.field); \ + p += sprintf(p, (lint_stat & UNIV_BM_LINT_##name) ? ", irq now active\n" : "\n"); + p += sprintf(p, "ACFAIL Interrupt:\t\t"); + REPORT_IRQ(ACFAIL, acfail); + p += sprintf(p, "SYSFAIL Interrupt:\t\t"); + REPORT_IRQ(SYSFAIL, sysfail); + p += sprintf(p, "SW_INT Interrupt:\t\t"); + REPORT_IRQ(SW_INT, sw_int); + p += sprintf(p, "SW_IACK Interrupt:\t\t"); + REPORT_IRQ(SW_IACK, sw_iack); + p += sprintf(p, "VERR Interrupt:\t\t\t"); + REPORT_IRQ(VERR, verr); + p += sprintf(p, "LERR Interrupt:\t\t\t"); + REPORT_IRQ(LERR, lerr); + p += sprintf(p, "LM Interrupt:\t\t\t"); + REPORT_IRQ(LM, lm); + p += sprintf(p, "MBOX Interrupt:\t\t\t"); + REPORT_IRQ(MBOX, mbox); + p += sprintf(p, "DMA Interrupt:\t\t\t"); + REPORT_IRQ(DMA, dma); + p += sprintf(p, "VIRQ7 Interrupt:\t\t"); + REPORT_IRQ(VIRQ7, virq[7 - 1]); + p += sprintf(p, "VIRQ6 Interrupt:\t\t"); + REPORT_IRQ(VIRQ6, virq[6 - 1]); + p += sprintf(p, "VIRQ5 Interrupt:\t\t"); + REPORT_IRQ(VIRQ5, virq[5 - 1]); + p += sprintf(p, "VIRQ4 Interrupt:\t\t"); + REPORT_IRQ(VIRQ4, virq[4 - 1]); + p += sprintf(p, "VIRQ3 Interrupt:\t\t"); + REPORT_IRQ(VIRQ3, virq[3 - 1]); + p += sprintf(p, "VIRQ2 Interrupt:\t\t"); + REPORT_IRQ(VIRQ2, virq[2 - 1]); + p += sprintf(p, "VIRQ1 Interrupt:\t\t"); + REPORT_IRQ(VIRQ1, virq[1 - 1]); + p += sprintf(p, "VOWN Interrupt:\t\t\t"); + REPORT_IRQ(VOWN, vown); + p += sprintf(p, "\n"); +#undef REPORT_IRQ + } + { + unsigned long vrai_ctl; + + vrai_ctl = read_register(VRAI_CTL); + if (vrai_ctl & UNIV_BM_VRAI_CTL_EN) { + unsigned int vrai_bs; + + vrai_bs = read_register(VRAI_BS); + p += sprintf(p, + "VME Register Image:\t\tEnabled at VME-Address 0x%x\n", + vrai_bs); + } else + p += sprintf(p, "VME Register Image:\t\tDisabled\n"); + } + { + unsigned int slsi; + + slsi = read_register(SLSI); + if (slsi & UNIV_BM_SLSI_EN) { + /* Not implemented */ + } else { + p += sprintf(p, "Special PCI Slave Image:\tDisabled\n"); + } + } + { + int i; + + for (i = 0; i < (vmechip_revision > 0 ? 8 : 4); i++) { + unsigned int ctl, bs, bd, to, vstart, vend; + + ctl = readl(vmechip_baseaddr + outCTL[i]); + bs = readl(vmechip_baseaddr + outBS[i]); + bd = readl(vmechip_baseaddr + outBD[i]); + to = readl(vmechip_baseaddr + outTO[i]); + + vstart = bs + to; + vend = bd + to; + + p += sprintf(p, "PCI Slave Image %d:\t\t", i); + if (ctl & UNIV_BM_LSI_CTL_EN) { + p += sprintf(p, "Enabled"); + if (ctl & UNIV_BM_LSI_CTL_PWEN) + p += sprintf(p, + ", Posted Write Enabled\n"); + else + p += sprintf(p, "\n"); + p += sprintf(p, + "\t\t\t\tPCI Addresses from 0x%x to 0x%x\n", + bs, bd); + p += sprintf(p, + "\t\t\t\tVME Addresses from 0x%x to 0x%x\n", + vstart, vend); + } else + p += sprintf(p, "Disabled\n"); + } + p += sprintf(p, "\n"); + } + { + int i; + for (i = 0; i < (vmechip_revision > 0 ? 8 : 4); i++) { + unsigned int ctl, bs, bd, to, vstart, vend; + + ctl = readl(vmechip_baseaddr + inCTL[i]); + bs = readl(vmechip_baseaddr + inBS[i]); + bd = readl(vmechip_baseaddr + inBD[i]); + to = readl(vmechip_baseaddr + inTO[i]); + vstart = bs + to; + vend = bd + to; + p += sprintf(p, "VME Slave Image %d:\t\t", i); + if (ctl & UNIV_BM_LSI_CTL_EN) { + p += sprintf(p, "Enabled"); + if (ctl & UNIV_BM_LSI_CTL_PWEN) + p += sprintf(p, + ", Posted Write Enabled\n"); + else + p += sprintf(p, "\n"); + p += sprintf(p, + "\t\t\t\tVME Addresses from 0x%x to 0x%x\n", + bs, bd); + p += sprintf(p, + "\t\t\t\tPCI Addresses from 0x%x to 0x%x\n", + vstart, vend); + } else + p += sprintf(p, "Disabled\n"); + } + } + + return p - buf; +} + +//---------------------------------------------------------------------------- +// uni_bus_error_chk() +//---------------------------------------------------------------------------- +int uni_bus_error_chk(int clrflag) +{ + int tmp; + tmp = readl(vmechip_baseaddr + PCI_COMMAND); + if (tmp & 0x08000000) { // S_TA is Set + if (clrflag) + writel(tmp | 0x08000000, + vmechip_baseaddr + PCI_COMMAND); + return (1); + } + return (0); +} + +//----------------------------------------------------------------------------- +// Function : DMA_uni_irqhandler +// Inputs : void +// Outputs : void +// Description: Saves DMA completion timestamp and then wakes up DMA queue +//----------------------------------------------------------------------------- +static void DMA_uni_irqhandler(void) +{ + uni_dma_irq_time = uni_irq_time; + wake_up(&dma_queue[0]); +} + +//----------------------------------------------------------------------------- +// Function : LERR_uni_irqhandler +// Inputs : void +// Outputs : void +// Description: +//----------------------------------------------------------------------------- +static void LERR_uni_irqhandler(void) +{ + int val; + + val = readl(vmechip_baseaddr + DGCS); + + if (!(val & 0x00000800)) { + printk(KERN_ERR + "ca91c042: LERR_uni_irqhandler DMA Read Error DGCS=%08X\n", + val); + + } +} + +//----------------------------------------------------------------------------- +// Function : VERR_uni_irqhandler +// Inputs : void +// Outputs : void +// Description: +//----------------------------------------------------------------------------- +static void VERR_uni_irqhandler(void) +{ + int val; + + val = readl(vmechip_baseaddr + DGCS); + + if (!(val & 0x00000800)) { + printk(KERN_ERR + "ca91c042: VERR_uni_irqhandler DMA Read Error DGCS=%08X\n", + val); + } + +} + +//----------------------------------------------------------------------------- +// Function : MB_uni_irqhandler +// Inputs : void +// Outputs : void +// Description: +//----------------------------------------------------------------------------- +static void MB_uni_irqhandler(int mbox_mask) +{ + if (vmechip_irq_overhead_ticks != 0) { + wake_up(&mbox_queue); + } +} + +//----------------------------------------------------------------------------- +// Function : LM_uni_irqhandler +// Inputs : void +// Outputs : void +// Description: +//----------------------------------------------------------------------------- +static void LM_uni_irqhandler(int lm_mask) +{ + uni_lm_event = lm_mask; + wake_up(&lm_queue); +} + +//----------------------------------------------------------------------------- +// Function : VIRQ_uni_irqhandler +// Inputs : void +// Outputs : void +// Description: +//----------------------------------------------------------------------------- +static void VIRQ_uni_irqhandler(int virq_mask) +{ + int iackvec, i; + + for (i = 7; i > 0; i--) { + if (virq_mask & (1 << i)) { + Interrupt_counters.virq[i - 1]++; + iackvec = readl(vmechip_baseaddr + vmevec[i - 1]); + vme_irqlog[i][iackvec]++; + } + } +} + +//----------------------------------------------------------------------------- +// Function : uni_irqhandler +// Inputs : int irq, void *dev_id, struct pt_regs *regs +// Outputs : void +// Description: +//----------------------------------------------------------------------------- +static irqreturn_t uni_irqhandler(int irq, void *dev_id) +{ + long stat, enable; + + if (dev_id != vmechip_baseaddr) + return IRQ_NONE; + + uni_irq_time = get_tbl(); + + stat = readl(vmechip_baseaddr + LINT_STAT); + writel(stat, vmechip_baseaddr + LINT_STAT); // Clear all pending ints + enable = readl(vmechip_baseaddr + LINT_EN); + stat = stat & enable; + if (stat & 0x0100) { + Interrupt_counters.dma++; + DMA_uni_irqhandler(); + } + if (stat & 0x0200) { + Interrupt_counters.lerr++; + LERR_uni_irqhandler(); + } + if (stat & 0x0400) { + Interrupt_counters.verr++; + VERR_uni_irqhandler(); + } + if (stat & 0xF0000) { + Interrupt_counters.mbox++; + MB_uni_irqhandler((stat & 0xF0000) >> 16); + } + if (stat & 0xF00000) { + Interrupt_counters.lm++; + LM_uni_irqhandler((stat & 0xF00000) >> 20); + } + if (stat & 0x0000FE) { + VIRQ_uni_irqhandler(stat & 0x0000FE); + } + if (stat & UNIV_BM_LINT_ACFAIL) { + Interrupt_counters.acfail++; + } + if (stat & UNIV_BM_LINT_SYSFAIL) { + Interrupt_counters.sysfail++; + } + if (stat & UNIV_BM_LINT_SW_INT) { + Interrupt_counters.sw_int++; + } + if (stat & UNIV_BM_LINT_SW_IACK) { + Interrupt_counters.sw_iack++; + } + if (stat & UNIV_BM_LINT_VOWN) { + Interrupt_counters.vown++; + } + + return IRQ_HANDLED; +} + +//----------------------------------------------------------------------------- +// Function : uni_generate_irq +// Description: +//----------------------------------------------------------------------------- +int uni_generate_irq(virqInfo_t * vmeIrq) +{ + int timeout; + int looptimeout; + + timeout = vmeIrq->waitTime; + if (timeout == 0) { + timeout++; // Wait at least 1 tick... + } + looptimeout = HZ / 20; // try for 1/20 second + + vmeIrq->timeOutFlag = 0; + + // Validate & setup vector register. + if (vmeIrq->vector & 1) { // Universe can only generate even vectors + return (-EINVAL); + } + writel(vmeIrq->vector << 24, vmechip_baseaddr + STATID); + + // Assert VMEbus IRQ + writel(1 << (vmeIrq->level + 24), vmechip_baseaddr + VINT_EN); + + // Wait for syscon to do iack + while (readl(vmechip_baseaddr + VINT_STAT) & + (1 << (vmeIrq->level + 24))) { + set_current_state(TASK_INTERRUPTIBLE); + schedule_timeout(looptimeout); + timeout = timeout - looptimeout; + if (timeout <= 0) { + vmeIrq->timeOutFlag = 1; + break; + } + } + + // Clear VMEbus IRQ bit + writel(0, vmechip_baseaddr + VINT_EN); + + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_set_arbiter +// Description: +//----------------------------------------------------------------------------- +int uni_set_arbiter(vmeArbiterCfg_t * vmeArb) +{ + int temp_ctl = 0; + int vbto = 0; + + temp_ctl = readl(vmechip_baseaddr + MISC_CTL); + temp_ctl &= 0x00FFFFFF; + + if (vmeArb->globalTimeoutTimer == 0xFFFFFFFF) { + vbto = 7; + } else if (vmeArb->globalTimeoutTimer > 1024) { + return (-EINVAL); + } else if (vmeArb->globalTimeoutTimer == 0) { + vbto = 0; + } else { + vbto = 1; + while ((16 * (1 << (vbto - 1))) < vmeArb->globalTimeoutTimer) { + vbto += 1; + } + } + temp_ctl |= (vbto << 28); + + if (vmeArb->arbiterMode == VME_PRIORITY_MODE) { + temp_ctl |= 1 << 26; + } + + if (vmeArb->arbiterTimeoutFlag) { + temp_ctl |= 2 << 24; + } + + writel(temp_ctl, vmechip_baseaddr + MISC_CTL); + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_get_arbiter +// Description: +//----------------------------------------------------------------------------- +int uni_get_arbiter(vmeArbiterCfg_t * vmeArb) +{ + int temp_ctl = 0; + int vbto = 0; + + temp_ctl = readl(vmechip_baseaddr + MISC_CTL); + + vbto = (temp_ctl >> 28) & 0xF; + if (vbto != 0) { + vmeArb->globalTimeoutTimer = (16 * (1 << (vbto - 1))); + } + + if (temp_ctl & (1 << 26)) { + vmeArb->arbiterMode = VME_PRIORITY_MODE; + } else { + vmeArb->arbiterMode = VME_R_ROBIN_MODE; + } + + if (temp_ctl & (3 << 24)) { + vmeArb->arbiterTimeoutFlag = 1; + } + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_set_requestor +// Description: +//----------------------------------------------------------------------------- +int uni_set_requestor(vmeRequesterCfg_t * vmeReq) +{ + int temp_ctl = 0; + + temp_ctl = readl(vmechip_baseaddr + MAST_CTL); + temp_ctl &= 0xFF0FFFFF; + + if (vmeReq->releaseMode == 1) { + temp_ctl |= (1 << 20); + } + + if (vmeReq->fairMode == 1) { + temp_ctl |= (1 << 21); + } + + temp_ctl |= (vmeReq->requestLevel << 22); + + writel(temp_ctl, vmechip_baseaddr + MAST_CTL); + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_get_requestor +// Description: +//----------------------------------------------------------------------------- +int uni_get_requestor(vmeRequesterCfg_t * vmeReq) +{ + int temp_ctl = 0; + + temp_ctl = readl(vmechip_baseaddr + MAST_CTL); + + if (temp_ctl & (1 << 20)) { + vmeReq->releaseMode = 1; + } + + if (temp_ctl & (1 << 21)) { + vmeReq->fairMode = 1; + } + + vmeReq->requestLevel = (temp_ctl & 0xC00000) >> 22; + + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_set_in_bound +// Description: +//----------------------------------------------------------------------------- +int uni_set_in_bound(vmeInWindowCfg_t * vmeIn) +{ + int temp_ctl = 0; + + // Verify input data + if (vmeIn->windowNbr > 7) { + return (-EINVAL); + } + if ((vmeIn->vmeAddrU) || (vmeIn->windowSizeU) || (vmeIn->pciAddrU)) { + return (-EINVAL); + } + if ((vmeIn->vmeAddrL & 0xFFF) || + (vmeIn->windowSizeL & 0xFFF) || (vmeIn->pciAddrL & 0xFFF)) { + return (-EINVAL); + } + + if (vmeIn->bcastRespond2esst) { + return (-EINVAL); + } + switch (vmeIn->addrSpace) { + case VME_A64: + case VME_CRCSR: + case VME_USER3: + case VME_USER4: + return (-EINVAL); + case VME_A16: + temp_ctl |= 0x00000; + break; + case VME_A24: + temp_ctl |= 0x10000; + break; + case VME_A32: + temp_ctl |= 0x20000; + break; + case VME_USER1: + temp_ctl |= 0x60000; + break; + case VME_USER2: + temp_ctl |= 0x70000; + break; + } + + // Disable while we are mucking around + writel(0x00000000, vmechip_baseaddr + inCTL[vmeIn->windowNbr]); + writel(vmeIn->vmeAddrL, vmechip_baseaddr + inBS[vmeIn->windowNbr]); + writel(vmeIn->vmeAddrL + vmeIn->windowSizeL, + vmechip_baseaddr + inBD[vmeIn->windowNbr]); + writel(vmeIn->pciAddrL - vmeIn->vmeAddrL, + vmechip_baseaddr + inTO[vmeIn->windowNbr]); + + // Setup CTL register. + if (vmeIn->wrPostEnable) + temp_ctl |= 0x40000000; + if (vmeIn->prefetchEnable) + temp_ctl |= 0x20000000; + if (vmeIn->rmwLock) + temp_ctl |= 0x00000040; + if (vmeIn->data64BitCapable) + temp_ctl |= 0x00000080; + if (vmeIn->userAccessType & VME_USER) + temp_ctl |= 0x00100000; + if (vmeIn->userAccessType & VME_SUPER) + temp_ctl |= 0x00200000; + if (vmeIn->dataAccessType & VME_DATA) + temp_ctl |= 0x00400000; + if (vmeIn->dataAccessType & VME_PROG) + temp_ctl |= 0x00800000; + + // Write ctl reg without enable + writel(temp_ctl, vmechip_baseaddr + inCTL[vmeIn->windowNbr]); + + if (vmeIn->windowEnable) + temp_ctl |= 0x80000000; + + writel(temp_ctl, vmechip_baseaddr + inCTL[vmeIn->windowNbr]); + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_get_in_bound +// Description: +//----------------------------------------------------------------------------- +int uni_get_in_bound(vmeInWindowCfg_t * vmeIn) +{ + int temp_ctl = 0; + + // Verify input data + if (vmeIn->windowNbr > 7) { + return (-EINVAL); + } + // Get Window mappings. + vmeIn->vmeAddrL = readl(vmechip_baseaddr + inBS[vmeIn->windowNbr]); + vmeIn->pciAddrL = vmeIn->vmeAddrL + + readl(vmechip_baseaddr + inTO[vmeIn->windowNbr]); + vmeIn->windowSizeL = readl(vmechip_baseaddr + inBD[vmeIn->windowNbr]) - + vmeIn->vmeAddrL; + + temp_ctl = readl(vmechip_baseaddr + inCTL[vmeIn->windowNbr]); + + // Get Control & BUS attributes + if (temp_ctl & 0x40000000) + vmeIn->wrPostEnable = 1; + if (temp_ctl & 0x20000000) + vmeIn->prefetchEnable = 1; + if (temp_ctl & 0x00000040) + vmeIn->rmwLock = 1; + if (temp_ctl & 0x00000080) + vmeIn->data64BitCapable = 1; + if (temp_ctl & 0x00100000) + vmeIn->userAccessType |= VME_USER; + if (temp_ctl & 0x00200000) + vmeIn->userAccessType |= VME_SUPER; + if (temp_ctl & 0x00400000) + vmeIn->dataAccessType |= VME_DATA; + if (temp_ctl & 0x00800000) + vmeIn->dataAccessType |= VME_PROG; + if (temp_ctl & 0x80000000) + vmeIn->windowEnable = 1; + + switch ((temp_ctl & 0x70000) >> 16) { + case 0x0: + vmeIn->addrSpace = VME_A16; + break; + case 0x1: + vmeIn->addrSpace = VME_A24; + break; + case 0x2: + vmeIn->addrSpace = VME_A32; + break; + case 0x6: + vmeIn->addrSpace = VME_USER1; + break; + case 0x7: + vmeIn->addrSpace = VME_USER2; + break; + } + + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_set_out_bound +// Description: +//----------------------------------------------------------------------------- +int uni_set_out_bound(vmeOutWindowCfg_t * vmeOut) +{ + int temp_ctl = 0; + + // Verify input data + if (vmeOut->windowNbr > 7) { + return (-EINVAL); + } + if ((vmeOut->xlatedAddrU) || (vmeOut->windowSizeU) + || (vmeOut->pciBusAddrU)) { + return (-EINVAL); + } + if ((vmeOut->xlatedAddrL & 0xFFF) || + (vmeOut->windowSizeL & 0xFFF) || (vmeOut->pciBusAddrL & 0xFFF)) { + return (-EINVAL); + } + if (vmeOut->bcastSelect2esst) { + return (-EINVAL); + } + switch (vmeOut->addrSpace) { + case VME_A64: + case VME_USER3: + case VME_USER4: + return (-EINVAL); + case VME_A16: + temp_ctl |= 0x00000; + break; + case VME_A24: + temp_ctl |= 0x10000; + break; + case VME_A32: + temp_ctl |= 0x20000; + break; + case VME_CRCSR: + temp_ctl |= 0x50000; + break; + case VME_USER1: + temp_ctl |= 0x60000; + break; + case VME_USER2: + temp_ctl |= 0x70000; + break; + } + + // Disable while we are mucking around + writel(0x00000000, vmechip_baseaddr + outCTL[vmeOut->windowNbr]); + writel(vmeOut->pciBusAddrL, + vmechip_baseaddr + outBS[vmeOut->windowNbr]); + writel(vmeOut->pciBusAddrL + vmeOut->windowSizeL, + vmechip_baseaddr + outBD[vmeOut->windowNbr]); + writel(vmeOut->xlatedAddrL - vmeOut->pciBusAddrL, + vmechip_baseaddr + outTO[vmeOut->windowNbr]); + + // Sanity check. + if (vmeOut->pciBusAddrL != + readl(vmechip_baseaddr + outBS[vmeOut->windowNbr])) { + printk(KERN_ERR + "ca91c042: out window: %x, failed to configure\n", + vmeOut->windowNbr); + return (-EINVAL); + } + + if (vmeOut->pciBusAddrL + vmeOut->windowSizeL != + readl(vmechip_baseaddr + outBD[vmeOut->windowNbr])) { + printk(KERN_ERR + "ca91c042: out window: %x, failed to configure\n", + vmeOut->windowNbr); + return (-EINVAL); + } + + if (vmeOut->xlatedAddrL - vmeOut->pciBusAddrL != + readl(vmechip_baseaddr + outTO[vmeOut->windowNbr])) { + printk(KERN_ERR + "ca91c042: out window: %x, failed to configure\n", + vmeOut->windowNbr); + return (-EINVAL); + } + // Setup CTL register. + if (vmeOut->wrPostEnable) + temp_ctl |= 0x40000000; + if (vmeOut->userAccessType & VME_SUPER) + temp_ctl |= 0x001000; + if (vmeOut->dataAccessType & VME_PROG) + temp_ctl |= 0x004000; + if (vmeOut->maxDataWidth == VME_D16) + temp_ctl |= 0x00400000; + if (vmeOut->maxDataWidth == VME_D32) + temp_ctl |= 0x00800000; + if (vmeOut->maxDataWidth == VME_D64) + temp_ctl |= 0x00C00000; + if (vmeOut->xferProtocol & (VME_BLT | VME_MBLT)) + temp_ctl |= 0x00000100; + + // Write ctl reg without enable + writel(temp_ctl, vmechip_baseaddr + outCTL[vmeOut->windowNbr]); + + if (vmeOut->windowEnable) + temp_ctl |= 0x80000000; + + writel(temp_ctl, vmechip_baseaddr + outCTL[vmeOut->windowNbr]); + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_get_out_bound +// Description: +//----------------------------------------------------------------------------- +int uni_get_out_bound(vmeOutWindowCfg_t * vmeOut) +{ + int temp_ctl = 0; + + // Verify input data + if (vmeOut->windowNbr > 7) { + return (-EINVAL); + } + // Get Window mappings. + vmeOut->pciBusAddrL = + readl(vmechip_baseaddr + outBS[vmeOut->windowNbr]); + vmeOut->xlatedAddrL = + vmeOut->pciBusAddrL + readl(vmechip_baseaddr + + outTO[vmeOut->windowNbr]); + vmeOut->windowSizeL = + readl(vmechip_baseaddr + outBD[vmeOut->windowNbr]) - + vmeOut->pciBusAddrL; + + temp_ctl = readl(vmechip_baseaddr + outCTL[vmeOut->windowNbr]); + + // Get Control & BUS attributes + if (temp_ctl & 0x40000000) + vmeOut->wrPostEnable = 1; + if (temp_ctl & 0x001000) + vmeOut->userAccessType = VME_SUPER; + else + vmeOut->userAccessType = VME_USER; + if (temp_ctl & 0x004000) + vmeOut->dataAccessType = VME_PROG; + else + vmeOut->dataAccessType = VME_DATA; + if (temp_ctl & 0x80000000) + vmeOut->windowEnable = 1; + + switch ((temp_ctl & 0x00C00000) >> 22) { + case 0: + vmeOut->maxDataWidth = VME_D8; + break; + case 1: + vmeOut->maxDataWidth = VME_D16; + break; + case 2: + vmeOut->maxDataWidth = VME_D32; + break; + case 3: + vmeOut->maxDataWidth = VME_D64; + break; + } + if (temp_ctl & 0x00000100) + vmeOut->xferProtocol = VME_BLT; + else + vmeOut->xferProtocol = VME_SCT; + + switch ((temp_ctl & 0x70000) >> 16) { + case 0x0: + vmeOut->addrSpace = VME_A16; + break; + case 0x1: + vmeOut->addrSpace = VME_A24; + break; + case 0x2: + vmeOut->addrSpace = VME_A32; + break; + case 0x5: + vmeOut->addrSpace = VME_CRCSR; + break; + case 0x6: + vmeOut->addrSpace = VME_USER1; + break; + case 0x7: + vmeOut->addrSpace = VME_USER2; + break; + } + + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_setup_lm +// Description: +//----------------------------------------------------------------------------- +int uni_setup_lm(vmeLmCfg_t * vmeLm) +{ + int temp_ctl = 0; + + if (vmeLm->addrU) { + return (-EINVAL); + } + switch (vmeLm->addrSpace) { + case VME_A64: + case VME_USER3: + case VME_USER4: + return (-EINVAL); + case VME_A16: + temp_ctl |= 0x00000; + break; + case VME_A24: + temp_ctl |= 0x10000; + break; + case VME_A32: + temp_ctl |= 0x20000; + break; + case VME_CRCSR: + temp_ctl |= 0x50000; + break; + case VME_USER1: + temp_ctl |= 0x60000; + break; + case VME_USER2: + temp_ctl |= 0x70000; + break; + } + + // Disable while we are mucking around + writel(0x00000000, vmechip_baseaddr + LM_CTL); + + writel(vmeLm->addr, vmechip_baseaddr + LM_BS); + + // Setup CTL register. + if (vmeLm->userAccessType & VME_SUPER) + temp_ctl |= 0x00200000; + if (vmeLm->userAccessType & VME_USER) + temp_ctl |= 0x00100000; + if (vmeLm->dataAccessType & VME_PROG) + temp_ctl |= 0x00800000; + if (vmeLm->dataAccessType & VME_DATA) + temp_ctl |= 0x00400000; + + uni_lm_event = 0; + + // Write ctl reg and enable + writel(0x80000000 | temp_ctl, vmechip_baseaddr + LM_CTL); + temp_ctl = readl(vmechip_baseaddr + LM_CTL); + + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_wait_lm +// Description: +//----------------------------------------------------------------------------- +int uni_wait_lm(vmeLmCfg_t * vmeLm) +{ + unsigned long flags; + unsigned int tmp; + + spin_lock_irqsave(&lm_lock, flags); + tmp = uni_lm_event; + spin_unlock_irqrestore(&lm_lock, flags); + if (tmp == 0) { + if (vmeLm->lmWait < 10) + vmeLm->lmWait = 10; + interruptible_sleep_on_timeout(&lm_queue, vmeLm->lmWait); + } + writel(0x00000000, vmechip_baseaddr + LM_CTL); + vmeLm->lmEvents = uni_lm_event; + + return (0); +} + +#define SWIZZLE(X) ( ((X & 0xFF000000) >> 24) | ((X & 0x00FF0000) >> 8) | ((X & 0x0000FF00) << 8) | ((X & 0x000000FF) << 24)) + +//----------------------------------------------------------------------------- +// Function : uni_do_rmw +// Description: +//----------------------------------------------------------------------------- +int uni_do_rmw(vmeRmwCfg_t * vmeRmw) +{ + int temp_ctl = 0; + int tempBS = 0; + int tempBD = 0; + int tempTO = 0; + int vmeBS = 0; + int vmeBD = 0; + int *rmw_pci_data_ptr = NULL; + int *vaDataPtr = NULL; + int i; + vmeOutWindowCfg_t vmeOut; + if (vmeRmw->maxAttempts < 1) { + return (-EINVAL); + } + if (vmeRmw->targetAddrU) { + return (-EINVAL); + } + // Find the PCI address that maps to the desired VME address + for (i = 0; i < 8; i++) { + temp_ctl = readl(vmechip_baseaddr + outCTL[i]); + if ((temp_ctl & 0x80000000) == 0) { + continue; + } + memset(&vmeOut, 0, sizeof(vmeOut)); + vmeOut.windowNbr = i; + uni_get_out_bound(&vmeOut); + if (vmeOut.addrSpace != vmeRmw->addrSpace) { + continue; + } + tempBS = readl(vmechip_baseaddr + outBS[i]); + tempBD = readl(vmechip_baseaddr + outBD[i]); + tempTO = readl(vmechip_baseaddr + outTO[i]); + vmeBS = tempBS + tempTO; + vmeBD = tempBD + tempTO; + if ((vmeRmw->targetAddr >= vmeBS) && + (vmeRmw->targetAddr < vmeBD)) { + rmw_pci_data_ptr = + (int *)(tempBS + (vmeRmw->targetAddr - vmeBS)); + vaDataPtr = + (int *)(out_image_va[i] + + (vmeRmw->targetAddr - vmeBS)); + break; + } + } + + // If no window - fail. + if (rmw_pci_data_ptr == NULL) { + return (-EINVAL); + } + // Setup the RMW registers. + writel(0, vmechip_baseaddr + SCYC_CTL); + writel(SWIZZLE(vmeRmw->enableMask), vmechip_baseaddr + SCYC_EN); + writel(SWIZZLE(vmeRmw->compareData), vmechip_baseaddr + SCYC_CMP); + writel(SWIZZLE(vmeRmw->swapData), vmechip_baseaddr + SCYC_SWP); + writel((int)rmw_pci_data_ptr, vmechip_baseaddr + SCYC_ADDR); + writel(1, vmechip_baseaddr + SCYC_CTL); + + // Run the RMW cycle until either success or max attempts. + vmeRmw->numAttempts = 1; + while (vmeRmw->numAttempts <= vmeRmw->maxAttempts) { + + if ((readl(vaDataPtr) & vmeRmw->enableMask) == + (vmeRmw->swapData & vmeRmw->enableMask)) { + + writel(0, vmechip_baseaddr + SCYC_CTL); + break; + + } + vmeRmw->numAttempts++; + } + + // If no success, set num Attempts to be greater than max attempts + if (vmeRmw->numAttempts > vmeRmw->maxAttempts) { + vmeRmw->numAttempts = vmeRmw->maxAttempts + 1; + } + + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uniSetupDctlReg +// Description: +//----------------------------------------------------------------------------- +int uniSetupDctlReg(vmeDmaPacket_t * vmeDma, int *dctlregreturn) +{ + unsigned int dctlreg = 0x80; + struct vmeAttr *vmeAttr; + + if (vmeDma->srcBus == VME_DMA_VME) { + dctlreg = 0; + vmeAttr = &vmeDma->srcVmeAttr; + } else { + dctlreg = 0x80000000; + vmeAttr = &vmeDma->dstVmeAttr; + } + + switch (vmeAttr->maxDataWidth) { + case VME_D8: + break; + case VME_D16: + dctlreg |= 0x00400000; + break; + case VME_D32: + dctlreg |= 0x00800000; + break; + case VME_D64: + dctlreg |= 0x00C00000; + break; + } + + switch (vmeAttr->addrSpace) { + case VME_A16: + break; + case VME_A24: + dctlreg |= 0x00010000; + break; + case VME_A32: + dctlreg |= 0x00020000; + break; + case VME_USER1: + dctlreg |= 0x00060000; + break; + case VME_USER2: + dctlreg |= 0x00070000; + break; + + case VME_A64: // not supported in Universe DMA + case VME_CRCSR: + case VME_USER3: + case VME_USER4: + return (-EINVAL); + break; + } + if (vmeAttr->userAccessType == VME_PROG) { + dctlreg |= 0x00004000; + } + if (vmeAttr->dataAccessType == VME_SUPER) { + dctlreg |= 0x00001000; + } + if (vmeAttr->xferProtocol != VME_SCT) { + dctlreg |= 0x00000100; + } + *dctlregreturn = dctlreg; + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_start_dma +// Description: +//----------------------------------------------------------------------------- +unsigned int +uni_start_dma(int channel, unsigned int dgcsreg, TDMA_Cmd_Packet * vmeLL) +{ + unsigned int val; + + // Setup registers as needed for direct or chained. + if (dgcsreg & 0x8000000) { + writel(0, vmechip_baseaddr + DTBC); + writel((unsigned int)vmeLL, vmechip_baseaddr + DCPP); + } else { +#if 0 + printk("Starting: DGCS = %08x\n", dgcsreg); + printk("Starting: DVA = %08x\n", readl(&vmeLL->dva)); + printk("Starting: DLV = %08x\n", readl(&vmeLL->dlv)); + printk("Starting: DTBC = %08x\n", readl(&vmeLL->dtbc)); + printk("Starting: DCTL = %08x\n", readl(&vmeLL->dctl)); +#endif + // Write registers + writel(readl(&vmeLL->dva), vmechip_baseaddr + DVA); + writel(readl(&vmeLL->dlv), vmechip_baseaddr + DLA); + writel(readl(&vmeLL->dtbc), vmechip_baseaddr + DTBC); + writel(readl(&vmeLL->dctl), vmechip_baseaddr + DCTL); + writel(0, vmechip_baseaddr + DCPP); + } + + // Start the operation + writel(dgcsreg, vmechip_baseaddr + DGCS); + val = get_tbl(); + writel(dgcsreg | 0x8000000F, vmechip_baseaddr + DGCS); + return (val); +} + +//----------------------------------------------------------------------------- +// Function : uni_setup_dma +// Description: +//----------------------------------------------------------------------------- +TDMA_Cmd_Packet *uni_setup_dma(vmeDmaPacket_t * vmeDma) +{ + vmeDmaPacket_t *vmeCur; + int maxPerPage; + int currentLLcount; + TDMA_Cmd_Packet *startLL; + TDMA_Cmd_Packet *currentLL; + TDMA_Cmd_Packet *nextLL; + unsigned int dctlreg = 0; + + maxPerPage = PAGESIZE / sizeof(TDMA_Cmd_Packet) - 1; + startLL = (TDMA_Cmd_Packet *) __get_free_pages(GFP_KERNEL, 0); + if (startLL == 0) { + return (startLL); + } + // First allocate pages for descriptors and create linked list + vmeCur = vmeDma; + currentLL = startLL; + currentLLcount = 0; + while (vmeCur != 0) { + if (vmeCur->pNextPacket != 0) { + currentLL->dcpp = (unsigned int)(currentLL + 1); + currentLLcount++; + if (currentLLcount >= maxPerPage) { + currentLL->dcpp = + __get_free_pages(GFP_KERNEL, 0); + currentLLcount = 0; + } + currentLL = (TDMA_Cmd_Packet *) currentLL->dcpp; + } else { + currentLL->dcpp = (unsigned int)0; + } + vmeCur = vmeCur->pNextPacket; + } + + // Next fill in information for each descriptor + vmeCur = vmeDma; + currentLL = startLL; + while (vmeCur != 0) { + if (vmeCur->srcBus == VME_DMA_VME) { + writel(vmeCur->srcAddr, ¤tLL->dva); + writel(vmeCur->dstAddr, ¤tLL->dlv); + } else { + writel(vmeCur->srcAddr, ¤tLL->dlv); + writel(vmeCur->dstAddr, ¤tLL->dva); + } + uniSetupDctlReg(vmeCur, &dctlreg); + writel(dctlreg, ¤tLL->dctl); + writel(vmeCur->byteCount, ¤tLL->dtbc); + + currentLL = (TDMA_Cmd_Packet *) currentLL->dcpp; + vmeCur = vmeCur->pNextPacket; + } + + // Convert Links to PCI addresses. + currentLL = startLL; + while (currentLL != 0) { + nextLL = (TDMA_Cmd_Packet *) currentLL->dcpp; + if (nextLL == 0) { + writel(1, ¤tLL->dcpp); + } else { + writel((unsigned int)virt_to_bus(nextLL), + ¤tLL->dcpp); + } + currentLL = nextLL; + } + + // Return pointer to descriptors list + return (startLL); +} + +//----------------------------------------------------------------------------- +// Function : uni_free_dma +// Description: +//----------------------------------------------------------------------------- +int uni_free_dma(TDMA_Cmd_Packet * startLL) +{ + TDMA_Cmd_Packet *currentLL; + TDMA_Cmd_Packet *prevLL; + TDMA_Cmd_Packet *nextLL; + unsigned int dcppreg; + + // Convert Links to virtual addresses. + currentLL = startLL; + while (currentLL != 0) { + dcppreg = readl(¤tLL->dcpp); + dcppreg &= ~6; + if (dcppreg & 1) { + currentLL->dcpp = 0; + } else { + currentLL->dcpp = (unsigned int)bus_to_virt(dcppreg); + } + currentLL = (TDMA_Cmd_Packet *) currentLL->dcpp; + } + + // Free all pages associated with the descriptors. + currentLL = startLL; + prevLL = currentLL; + while (currentLL != 0) { + nextLL = (TDMA_Cmd_Packet *) currentLL->dcpp; + if (currentLL + 1 != nextLL) { + free_pages((int)prevLL, 0); + prevLL = nextLL; + } + currentLL = nextLL; + } + + // Return pointer to descriptors list + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_do_dma +// Description: +//----------------------------------------------------------------------------- +int uni_do_dma(vmeDmaPacket_t * vmeDma) +{ + unsigned int dgcsreg = 0; + unsigned int dctlreg = 0; + int val; + int channel, x; + vmeDmaPacket_t *curDma; + TDMA_Cmd_Packet *dmaLL; + + // Sanity check the VME chain. + channel = vmeDma->channel_number; + if (channel > 0) { + return (-EINVAL); + } + curDma = vmeDma; + while (curDma != 0) { + if (curDma->byteCount == 0) { + return (-EINVAL); + } + if (curDma->byteCount >= 0x1000000) { + return (-EINVAL); + } + if ((curDma->srcAddr & 7) != (curDma->dstAddr & 7)) { + return (-EINVAL); + } + switch (curDma->srcBus) { + case VME_DMA_PCI: + if (curDma->dstBus != VME_DMA_VME) { + return (-EINVAL); + } + break; + case VME_DMA_VME: + if (curDma->dstBus != VME_DMA_PCI) { + return (-EINVAL); + } + break; + default: + return (-EINVAL); + break; + } + if (uniSetupDctlReg(curDma, &dctlreg) < 0) { + return (-EINVAL); + } + + curDma = curDma->pNextPacket; + if (curDma == vmeDma) { // Endless Loop! + return (-EINVAL); + } + } + + // calculate control register + if (vmeDma->pNextPacket != 0) { + dgcsreg = 0x8000000; + } else { + dgcsreg = 0; + } + + for (x = 0; x < 8; x++) { // vme block size + if ((256 << x) >= vmeDma->maxVmeBlockSize) { + break; + } + } + if (x == 8) + x = 7; + dgcsreg |= (x << 20); + + if (vmeDma->vmeBackOffTimer) { + for (x = 1; x < 8; x++) { // vme timer + if ((16 << (x - 1)) >= vmeDma->vmeBackOffTimer) { + break; + } + } + if (x == 8) + x = 7; + dgcsreg |= (x << 16); + } + // Setup the dma chain + dmaLL = uni_setup_dma(vmeDma); + + // Start the DMA + if (dgcsreg & 0x8000000) { + vmeDma->vmeDmaStartTick = + uni_start_dma(channel, dgcsreg, + (TDMA_Cmd_Packet *) virt_to_phys(dmaLL)); + } else { + vmeDma->vmeDmaStartTick = + uni_start_dma(channel, dgcsreg, dmaLL); + } + + wait_event_interruptible(dma_queue[0], + readl(vmechip_baseaddr + DGCS) & 0x800); + + val = readl(vmechip_baseaddr + DGCS); + writel(val | 0xF00, vmechip_baseaddr + DGCS); + + vmeDma->vmeDmaStatus = 0; + vmeDma->vmeDmaStopTick = uni_dma_irq_time; + if (vmeDma->vmeDmaStopTick < vmeDma->vmeDmaStartTick) { + vmeDma->vmeDmaElapsedTime = + (0xFFFFFFFF - vmeDma->vmeDmaStartTick) + + vmeDma->vmeDmaStopTick; + } else { + vmeDma->vmeDmaElapsedTime = + vmeDma->vmeDmaStopTick - vmeDma->vmeDmaStartTick; + } + vmeDma->vmeDmaElapsedTime -= vmechip_irq_overhead_ticks; + vmeDma->vmeDmaElapsedTime /= (tb_speed / 1000000); + + if (!(val & 0x00000800)) { + vmeDma->vmeDmaStatus = val & 0x700; + printk(KERN_ERR + "ca91c042: DMA Error in DMA_uni_irqhandler DGCS=%08X\n", + val); + val = readl(vmechip_baseaddr + DCPP); + printk(KERN_ERR "ca91c042: DCPP=%08X\n", val); + val = readl(vmechip_baseaddr + DCTL); + printk(KERN_ERR "ca91c042: DCTL=%08X\n", val); + val = readl(vmechip_baseaddr + DTBC); + printk(KERN_ERR "ca91c042: DTBC=%08X\n", val); + val = readl(vmechip_baseaddr + DLA); + printk(KERN_ERR "ca91c042: DLA=%08X\n", val); + val = readl(vmechip_baseaddr + DVA); + printk(KERN_ERR "ca91c042: DVA=%08X\n", val); + + } + // Free the dma chain + uni_free_dma(dmaLL); + + return (0); +} + +//----------------------------------------------------------------------------- +// Function : uni_shutdown +// Description: Put VME bridge in quiescent state. +//----------------------------------------------------------------------------- +void uni_shutdown(void) +{ + writel(0, vmechip_baseaddr + LINT_EN); // Turn off Ints + + // Turn off the windows + writel(0x00800000, vmechip_baseaddr + LSI0_CTL); + writel(0x00800000, vmechip_baseaddr + LSI1_CTL); + writel(0x00800000, vmechip_baseaddr + LSI2_CTL); + writel(0x00800000, vmechip_baseaddr + LSI3_CTL); + writel(0x00F00000, vmechip_baseaddr + VSI0_CTL); + writel(0x00F00000, vmechip_baseaddr + VSI1_CTL); + writel(0x00F00000, vmechip_baseaddr + VSI2_CTL); + writel(0x00F00000, vmechip_baseaddr + VSI3_CTL); + if (vmechip_revision >= 2) { + writel(0x00800000, vmechip_baseaddr + LSI4_CTL); + writel(0x00800000, vmechip_baseaddr + LSI5_CTL); + writel(0x00800000, vmechip_baseaddr + LSI6_CTL); + writel(0x00800000, vmechip_baseaddr + LSI7_CTL); + writel(0x00F00000, vmechip_baseaddr + VSI4_CTL); + writel(0x00F00000, vmechip_baseaddr + VSI5_CTL); + writel(0x00F00000, vmechip_baseaddr + VSI6_CTL); + writel(0x00F00000, vmechip_baseaddr + VSI7_CTL); + } +} + +//----------------------------------------------------------------------------- +// Function : uni_init() +// Description: +//----------------------------------------------------------------------------- +int uni_init(void) +{ + int result; + unsigned int tmp; + unsigned int crcsr_addr; + unsigned int irqOverHeadStart; + int overHeadTicks; + + uni_shutdown(); + + // Write to Misc Register + // Set VME Bus Time-out + // Arbitration Mode + // DTACK Enable + tmp = readl(vmechip_baseaddr + MISC_CTL) & 0x0832BFFF; + tmp |= 0x76040000; + writel(tmp, vmechip_baseaddr + MISC_CTL); + if (tmp & 0x20000) { + vme_syscon = 1; + } else { + vme_syscon = 0; + } + + // Clear DMA status log + writel(0x00000F00, vmechip_baseaddr + DGCS); + // Clear and enable error log + writel(0x00800000, vmechip_baseaddr + L_CMDERR); + // Turn off location monitor + writel(0x00000000, vmechip_baseaddr + LM_CTL); + + // Initialize crcsr map + if (vme_slotnum != -1) { + writel(vme_slotnum << 27, vmechip_baseaddr + VCSR_BS); + } + crcsr_addr = readl(vmechip_baseaddr + VCSR_BS) >> 8; + writel((unsigned int)vmechip_interboard_datap - crcsr_addr, + vmechip_baseaddr + VCSR_TO); + if (vme_slotnum != -1) { + writel(0x80000000, vmechip_baseaddr + VCSR_CTL); + } + // Turn off interrupts + writel(0x00000000, vmechip_baseaddr + LINT_EN); // Disable interrupts in the Universe first + writel(0x00FFFFFF, vmechip_baseaddr + LINT_STAT); // Clear Any Pending Interrupts + writel(0x00000000, vmechip_baseaddr + VINT_EN); // Disable interrupts in the Universe first + + result = + request_irq(vmechip_irq, uni_irqhandler, IRQF_SHARED | IRQF_DISABLED, + "VMEBus (ca91c042)", vmechip_baseaddr); + if (result) { + printk(KERN_ERR + "ca91c042: can't get assigned pci irq vector %02X\n", + vmechip_irq); + return (0); + } else { + writel(0x0000, vmechip_baseaddr + LINT_MAP0); // Map all ints to 0 + writel(0x0000, vmechip_baseaddr + LINT_MAP1); // Map all ints to 0 + writel(0x0000, vmechip_baseaddr + LINT_MAP2); // Map all ints to 0 + } + + // Enable DMA, mailbox, VIRQ & LM Interrupts + if (vme_syscon) + tmp = 0x00FF07FE; + else + tmp = 0x00FF0700; + writel(tmp, vmechip_baseaddr + LINT_EN); + + // Do a quick sanity test of the bridge + if (readl(vmechip_baseaddr + LINT_EN) != tmp) { + return (0); + } + if (readl(vmechip_baseaddr + PCI_CLASS_REVISION) != 0x06800002) { + return (0); + } + for (tmp = 1; tmp < 0x80000000; tmp = tmp << 1) { + writel(tmp, vmechip_baseaddr + SCYC_EN); + writel(~tmp, vmechip_baseaddr + SCYC_CMP); + if (readl(vmechip_baseaddr + SCYC_EN) != tmp) { + return (0); + } + if (readl(vmechip_baseaddr + SCYC_CMP) != ~tmp) { + return (0); + } + } + + // do a mail box interrupt to calibrate the interrupt overhead. + + irqOverHeadStart = get_tbl(); + writel(0, vmechip_baseaddr + MBOX1); + for (tmp = 0; tmp < 10; tmp++) { + } + + irqOverHeadStart = get_tbl(); + writel(0, vmechip_baseaddr + MBOX1); + for (tmp = 0; tmp < 10; tmp++) { + } + + overHeadTicks = uni_irq_time - irqOverHeadStart; + if (overHeadTicks > 0) { + vmechip_irq_overhead_ticks = overHeadTicks; + } else { + vmechip_irq_overhead_ticks = 1; + } + return (1); +} --- /dev/null +++ b/drivers/staging/vme/bridges/vme_ca91cx42.h @@ -0,0 +1,403 @@ +/* + * ca91c042.h + * + * Support for the Tundra Universe 1 and Universe II VME bridge chips + * + * Author: Tom Armistead + * Updated and maintained by Ajit Prem + * Copyright 2004 Motorola Inc. + * + * Derived from ca91c042.h by Michael Wyrick + * + * This program is free software; you can redistribute it and/or modify it + * under the terms of the GNU General Public License as published by the + * Free Software Foundation; either version 2 of the License, or (at your + * option) any later version. + */ + +#ifndef _ca91c042_h +#define _ca91c042_h + +#ifndef PCI_VENDOR_ID_TUNDRA +#define PCI_VENDOR_ID_TUNDRA 0x10e3 +#endif + +#ifndef PCI_DEVICE_ID_TUNDRA_CA91C042 +#define PCI_DEVICE_ID_TUNDRA_CA91C042 0x0000 +#endif + +//----------------------------------------------------------------------------- +// Public Functions +//----------------------------------------------------------------------------- +// This is the typedef for a VmeIrqHandler +typedef void (*TirqHandler) (int vmeirq, int vector, void *dev_id, + struct pt_regs * regs); +// This is the typedef for a DMA Transfer Callback function +typedef void (*TDMAcallback) (int status); + +// Returns the PCI baseaddress of the Universe chip +char *Universe_BaseAddr(void); +// Returns the PCI IRQ That the universe is using +int Universe_IRQ(void); + +char *mapvme(unsigned int pci, unsigned int vme, unsigned int size, + int image, int ctl); +void unmapvme(char *ptr, int image); + +// Interrupt Stuff +void enable_vmeirq(unsigned int irq); +void disable_vmeirq(unsigned int irq); +int request_vmeirq(unsigned int irq, TirqHandler); +void free_vmeirq(unsigned int irq); + +// DMA Stuff + +int VME_Bus_Error(void); +int uni_procinfo(char *); + +#define IRQ_VOWN 0x0001 +#define IRQ_VIRQ1 0x0002 +#define IRQ_VIRQ2 0x0004 +#define IRQ_VIRQ3 0x0008 +#define IRQ_VIRQ4 0x0010 +#define IRQ_VIRQ5 0x0020 +#define IRQ_VIRQ6 0x0040 +#define IRQ_VIRQ7 0x0080 +#define IRQ_DMA 0x0100 +#define IRQ_LERR 0x0200 +#define IRQ_VERR 0x0400 +#define IRQ_res 0x0800 +#define IRQ_IACK 0x1000 +#define IRQ_SWINT 0x2000 +#define IRQ_SYSFAIL 0x4000 +#define IRQ_ACFAIL 0x8000 + +// See Page 2-77 in the Universe User Manual +typedef struct { + unsigned int dctl; // DMA Control + unsigned int dtbc; // Transfer Byte Count + unsigned int dlv; // PCI Address + unsigned int res1; // Reserved + unsigned int dva; // Vme Address + unsigned int res2; // Reserved + unsigned int dcpp; // Pointer to Numed Cmd Packet with rPN + unsigned int res3; // Reserved +} TDMA_Cmd_Packet; + +/* + * Below here is normaly not used by a user module + */ +#define DMATIMEOUT 2*HZ; + +// Define for the Universe +#define SEEK_SET 0 +#define SEEK_CUR 1 + +#define CONFIG_REG_SPACE 0xA0000000 + +/* Universe Register Offsets */ +/* general PCI configuration registers */ +#define UNIV_PCI_ID 0x000 +#define UNIV_PCI_CSR 0x004 +#define UNIV_PCI_CLASS 0x008 +#define UNIV_BM_PCI_CLASS_BASE 0xFF000000 +#define UNIV_OF_PCI_CLASS_BASE 24 +#define UNIV_BM_PCI_CLASS_SUB 0x00FF0000 +#define UNIV_OF_PCI_CLASS_SUB 16 +#define UNIV_BM_PCI_CLASS_PROG 0x0000FF00 +#define UNIV_OF_PCI_CLASS_PROG 8 +#define UNIV_BM_PCI_CLASS_RID 0x000000FF +#define UNIV_OF_PCI_CLASS_RID 0 + +#define UNIV_OF_PCI_CLASS_RID_UNIVERSE_I 0 +#define UNIV_OF_PCI_CLASS_RID_UNIVERSE_II 1 + +#define UNIV_PCI_MISC0 0x00C +#define UNIV_BM_PCI_MISC0_BISTC 0x80000000 +#define UNIV_BM_PCI_MISC0_SBIST 0x60000000 +#define UNIV_BM_PCI_MISC0_CCODE 0x0F000000 +#define UNIV_BM_PCI_MISC0_MFUNCT 0x00800000 +#define UNIV_BM_PCI_MISC0_LAYOUT 0x007F0000 +#define UNIV_BM_PCI_MISC0_LTIMER 0x0000FF00 +#define UNIV_OF_PCI_MISC0_LTIMER 8 +#define UNIV_PCI_BS 0x010 +#define UNIV_PCI_MISC1 0x03C + +#define UNIV_BM_LSI_CTL_EN 0x80000000 +#define UNIV_BM_LSI_CTL_PWEN 0x40000000 +#define UNIV_BM_LSI_CTL_VDW 0x00C00000 +#define UNIV_OF_LSI_CTL_VDW 22 +#define UNIV_BM_LSI_CTL_VAS 0x00070000 +#define UNIV_OF_LSI_CTL_VAS 16 +#define UNIV_BM_LSI_CTL_PGM 0x0000C000 +#define UNIV_OF_LSI_CTL_PGM 14 +#define UNIV_BM_LSI_CTL_SUPER 0x00003000 +#define UNIV_OF_LSI_CTL_SUPER 12 +#define UNIV_BM_LSI_CTL_VCT 0x00000100 +#define UNIV_BM_LSI_CTL_LAS 0x00000003 +#define UNIV_OF_LSI_CTL_LAS 0 +#define UNIV_BM_LSI_CTL_RESERVED (~ (UNIV_BM_LSI_CTL_EN | UNIV_BM_LSI_CTL_PWEN | UNIV_BM_LSI_CTL_VDW | UNIV_BM_LSI_CTL_VAS | UNIV_BM_LSI_CTL_PGM | UNIV_BM_LSI_CTL_SUPER | UNIV_BM_LSI_CTL_VCT | UNIV_BM_LSI_CTL_LAS)) + +#define PCI_SIZE_8 0x0001 +#define PCI_SIZE_16 0x0002 +#define PCI_SIZE_32 0x0003 + +#define IOCTL_SET_CTL 0xF001 +#define IOCTL_SET_BS 0xF002 +#define IOCTL_SET_BD 0xF003 +#define IOCTL_SET_TO 0xF004 +#define IOCTL_PCI_SIZE 0xF005 +#define IOCTL_SET_MODE 0xF006 +#define IOCTL_SET_WINT 0xF007 // Wait for interrupt before read + +#define LSI0_CTL 0x0100 +#define LSI0_BS 0x0104 +#define LSI0_BD 0x0108 +#define LSI0_TO 0x010C + +#define LSI1_CTL 0x0114 +#define LSI1_BS 0x0118 +#define LSI1_BD 0x011C +#define LSI1_TO 0x0120 + +#define LSI2_CTL 0x0128 +#define LSI2_BS 0x012C +#define LSI2_BD 0x0130 +#define LSI2_TO 0x0134 + +#define LSI3_CTL 0x013C +#define LSI3_BS 0x0140 +#define LSI3_BD 0x0144 +#define LSI3_TO 0x0148 + +#define LSI4_CTL 0x01A0 +#define LSI4_BS 0x01A4 +#define LSI4_BD 0x01A8 +#define LSI4_TO 0x01AC + +#define LSI5_CTL 0x01B4 +#define LSI5_BS 0x01B8 +#define LSI5_BD 0x01BC +#define LSI5_TO 0x01C0 + +#define LSI6_CTL 0x01C8 +#define LSI6_BS 0x01CC +#define LSI6_BD 0x01D0 +#define LSI6_TO 0x01D4 + +#define LSI7_CTL 0x01DC +#define LSI7_BS 0x01E0 +#define LSI7_BD 0x01E4 +#define LSI7_TO 0x01E8 + +#define SCYC_CTL 0x0170 +#define SCYC_ADDR 0x0174 +#define SCYC_EN 0x0178 +#define SCYC_CMP 0x017C +#define SCYC_SWP 0x0180 +#define LMISC 0x0184 +#define UNIV_BM_LMISC_CRT 0xF0000000 +#define UNIV_OF_LMISC_CRT 28 +#define UNIV_BM_LMISC_CWT 0x0F000000 +#define UNIV_OF_LMISC_CWT 24 +#define SLSI 0x0188 +#define UNIV_BM_SLSI_EN 0x80000000 +#define UNIV_BM_SLSI_PWEN 0x40000000 +#define UNIV_BM_SLSI_VDW 0x00F00000 +#define UNIV_OF_SLSI_VDW 20 +#define UNIV_BM_SLSI_PGM 0x0000F000 +#define UNIV_OF_SLSI_PGM 12 +#define UNIV_BM_SLSI_SUPER 0x00000F00 +#define UNIV_OF_SLSI_SUPER 8 +#define UNIV_BM_SLSI_BS 0x000000F6 +#define UNIV_OF_SLSI_BS 2 +#define UNIV_BM_SLSI_LAS 0x00000003 +#define UNIV_OF_SLSI_LAS 0 +#define UNIV_BM_SLSI_RESERVED 0x3F0F0000 +#define L_CMDERR 0x018C +#define LAERR 0x0190 + +#define DCTL 0x0200 +#define DTBC 0x0204 +#define DLA 0x0208 +#define DVA 0x0210 +#define DCPP 0x0218 +#define DGCS 0x0220 +#define D_LLUE 0x0224 + +#define LINT_EN 0x0300 +#define UNIV_BM_LINT_ACFAIL 0x00008000 +#define UNIV_BM_LINT_SYSFAIL 0x00004000 +#define UNIV_BM_LINT_SW_INT 0x00002000 +#define UNIV_BM_LINT_SW_IACK 0x00001000 +#define UNIV_BM_LINT_VERR 0x00000400 +#define UNIV_BM_LINT_LERR 0x00000200 +#define UNIV_BM_LINT_DMA 0x00000100 +#define UNIV_BM_LINT_LM 0x00F00000 +#define UNIV_BM_LINT_MBOX 0x000F0000 +#define UNIV_BM_LINT_VIRQ 0x000000FE +#define UNIV_BM_LINT_VIRQ7 0x00000080 +#define UNIV_BM_LINT_VIRQ6 0x00000040 +#define UNIV_BM_LINT_VIRQ5 0x00000020 +#define UNIV_BM_LINT_VIRQ4 0x00000010 +#define UNIV_BM_LINT_VIRQ3 0x00000008 +#define UNIV_BM_LINT_VIRQ2 0x00000004 +#define UNIV_BM_LINT_VIRQ1 0x00000002 +#define UNIV_BM_LINT_VOWN 0x00000001 +#define LINT_STAT 0x0304 +#define LINT_MAP0 0x0308 +#define LINT_MAP1 0x030C +#define VINT_EN 0x0310 +#define VINT_STAT 0x0314 +#define VINT_MAP0 0x0318 +#define VINT_MAP1 0x031C +#define STATID 0x0320 +#define V1_STATID 0x0324 +#define V2_STATID 0x0328 +#define V3_STATID 0x032C +#define V4_STATID 0x0330 +#define V5_STATID 0x0334 +#define V6_STATID 0x0338 +#define V7_STATID 0x033C +#define LINT_MAP2 0x0340 +#define VINT_MAP2 0x0344 + +#define MBOX0 0x0348 +#define MBOX1 0x034C +#define MBOX2 0x0350 +#define MBOX3 0x0354 +#define SEMA0 0x0358 +#define SEMA1 0x035C + +#define MAST_CTL 0x0400 +#define UNIV_BM_MAST_CTL_MAXRTRY 0xF0000000 +#define UNIV_OF_MAST_CTL_MAXRTRY 28 +#define UNIV_BM_MAST_CTL_PWON 0x0F000000 +#define UNIV_OF_MAST_CTL_PWON 24 +#define UNIV_BM_MAST_CTL_VRL 0x00C00000 +#define UNIV_OF_MAST_CTL_VRL 22 +#define UNIV_BM_MAST_CTL_VRM 0x00200000 +#define UNIV_BM_MAST_CTL_VREL 0x00100000 +#define UNIV_BM_MAST_CTL_VOWN 0x00080000 +#define UNIV_BM_MAST_CTL_VOWN_ACK 0x00040000 +#define UNIV_BM_MAST_CTL_PABS 0x00001000 +#define UNIV_BM_MAST_CTL_BUS_NO 0x0000000F +#define UNIV_OF_MAST_CTL_BUS_NO 0 + +#define MISC_CTL 0x0404 +#define UNIV_BM_MISC_CTL_VBTO 0xF0000000 +#define UNIV_OF_MISC_CTL_VBTO 28 +#define UNIV_BM_MISC_CTL_VARB 0x04000000 +#define UNIV_BM_MISC_CTL_VARBTO 0x03000000 +#define UNIV_OF_MISC_CTL_VARBTO 24 +#define UNIV_BM_MISC_CTL_SW_LRST 0x00800000 +#define UNIV_BM_MISC_CTL_SW_SRST 0x00400000 +#define UNIV_BM_MISC_CTL_BI 0x00100000 +#define UNIV_BM_MISC_CTL_ENGBI 0x00080000 +#define UNIV_BM_MISC_CTL_RESCIND 0x00040000 +#define UNIV_BM_MISC_CTL_SYSCON 0x00020000 +#define UNIV_BM_MISC_CTL_V64AUTO 0x00010000 +#define UNIV_BM_MISC_CTL_RESERVED 0x0820FFFF + +#define MISC_STAT 0x0408 +#define UNIV_BM_MISC_STAT_ENDIAN 0x80000000 +#define UNIV_BM_MISC_STAT_LCLSIZE 0x40000000 +#define UNIV_BM_MISC_STAT_DY4AUTO 0x08000000 +#define UNIV_BM_MISC_STAT_MYBBSY 0x00200000 +#define UNIV_BM_MISC_STAT_DY4DONE 0x00080000 +#define UNIV_BM_MISC_STAT_TXFE 0x00040000 +#define UNIV_BM_MISC_STAT_RXFE 0x00020000 +#define UNIV_BM_MISC_STAT_DY4AUTOID 0x0000FF00 +#define UNIV_OF_MISC_STAT_DY4AUTOID 8 + +#define USER_AM 0x040C + +#define VSI0_CTL 0x0F00 +#define VSI0_BS 0x0F04 +#define VSI0_BD 0x0F08 +#define VSI0_TO 0x0F0C + +#define VSI1_CTL 0x0F14 +#define VSI1_BS 0x0F18 +#define VSI1_BD 0x0F1C +#define VSI1_TO 0x0F20 + +#define VSI2_CTL 0x0F28 +#define VSI2_BS 0x0F2C +#define VSI2_BD 0x0F30 +#define VSI2_TO 0x0F34 + +#define VSI3_CTL 0x0F3C +#define VSI3_BS 0x0F40 +#define VSI3_BD 0x0F44 +#define VSI3_TO 0x0F48 + +#define LM_CTL 0x0F64 +#define LM_BS 0x0F68 + +#define VRAI_CTL 0x0F70 +#define UNIV_BM_VRAI_CTL_EN 0x80000000 +#define UNIV_BM_VRAI_CTL_PGM 0x00C00000 +#define UNIV_OF_VRAI_CTL_PGM 22 +#define UNIV_BM_VRAI_CTL_SUPER 0x00300000 +#define UNIV_OF_VRAI_CTL_SUPER 20 +#define UNIV_BM_VRAI_CTL_VAS 0x00030000 +#define UNIV_OF_VRAI_CTL_VAS 16 + +#define VRAI_BS 0x0F74 +#define VCSR_CTL 0x0F80 +#define VCSR_TO 0x0F84 +#define V_AMERR 0x0F88 +#define VAERR 0x0F8C + +#define VSI4_CTL 0x0F90 +#define VSI4_BS 0x0F94 +#define VSI4_BD 0x0F98 +#define VSI4_TO 0x0F9C + +#define VSI5_CTL 0x0FA4 +#define VSI5_BS 0x0FA8 +#define VSI5_BD 0x0FAC +#define VSI5_TO 0x0FB0 + +#define VSI6_CTL 0x0FB8 +#define VSI6_BS 0x0FBC +#define VSI6_BD 0x0FC0 +#define VSI6_TO 0x0FC4 + +#define VSI7_CTL 0x0FCC +#define VSI7_BS 0x0FD0 +#define VSI7_BD 0x0FD4 +#define VSI7_TO 0x0FD8 + +#define VCSR_CLR 0x0FF4 +#define VCSR_SET 0x0FF8 +#define VCSR_BS 0x0FFC + +// DMA General Control/Status Register DGCS (0x220) +// 32-24 || GO | STOPR | HALTR | 0 || CHAIN | 0 | 0 | 0 || +// 23-16 || VON || VOFF || +// 15-08 || ACT | STOP | HALT | 0 || DONE | LERR | VERR | P_ERR || +// 07-00 || 0 | INT_S | INT_H | 0 || I_DNE | I_LER | I_VER | I_PER || + +// VON - Length Per DMA VMEBus Transfer +// 0000 = None +// 0001 = 256 Bytes +// 0010 = 512 +// 0011 = 1024 +// 0100 = 2048 +// 0101 = 4096 +// 0110 = 8192 +// 0111 = 16384 + +// VOFF - wait between DMA tenures +// 0000 = 0 us +// 0001 = 16 +// 0010 = 32 +// 0011 = 64 +// 0100 = 128 +// 0101 = 256 +// 0110 = 512 +// 0111 = 1024 + +#endif /* _ca91c042_h */ --- a/drivers/staging/vme/Kconfig +++ b/drivers/staging/vme/Kconfig @@ -10,7 +10,7 @@ menuconfig VME if VME -#source "drivers/staging/vme/bridges/Kconfig" +source "drivers/staging/vme/bridges/Kconfig" source "drivers/staging/vme/devices/Kconfig" --- a/drivers/staging/vme/Makefile +++ b/drivers/staging/vme/Makefile @@ -3,5 +3,5 @@ # obj-$(CONFIG_VME) += vme.o -#obj-y += bridges/ +obj-y += bridges/ obj-y += devices/ -- To unsubscribe from this list: send the line "unsubscribe linux-kernel" in the body of a message to majordomo@vger.kernel.org More majordomo info at http://vger.kernel.org/majordomo-info.html Please read the FAQ at http://www.tux.org/lkml/