/* * IBM Hot Plug Controller Driver * * Written By: Jyoti Shah, IBM Corporation * * Copyright (C) 2001-2003 IBM Corp. * * All rights reserved. * * 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. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or * NON INFRINGEMENT. See the GNU General Public License for more * details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. * * Send feedback to <gregkh@us.ibm.com> * <jshah@us.ibm.com> * */ #include <linux/wait.h> #include <linux/time.h> #include <linux/delay.h> #include <linux/module.h> #include <linux/pci.h> #include <linux/init.h> #include <linux/mutex.h> #include <linux/sched.h> #include <linux/semaphore.h> #include <linux/kthread.h> #include "ibmphp.h" static int to_debug = 0; #define debug_polling(fmt, arg...) do { if (to_debug) debug (fmt, arg); } while (0) //---------------------------------------------------------------------------- // timeout values //---------------------------------------------------------------------------- #define CMD_COMPLETE_TOUT_SEC 60 // give HPC 60 sec to finish cmd #define HPC_CTLR_WORKING_TOUT 60 // give HPC 60 sec to finish cmd #define HPC_GETACCESS_TIMEOUT 60 // seconds #define POLL_INTERVAL_SEC 2 // poll HPC every 2 seconds #define POLL_LATCH_CNT 5 // poll latch 5 times, then poll slots //---------------------------------------------------------------------------- // Winnipeg Architected Register Offsets //---------------------------------------------------------------------------- #define WPG_I2CMBUFL_OFFSET 0x08 // I2C Message Buffer Low #define WPG_I2CMOSUP_OFFSET 0x10 // I2C Master Operation Setup Reg #define WPG_I2CMCNTL_OFFSET 0x20 // I2C Master Control Register #define WPG_I2CPARM_OFFSET 0x40 // I2C Parameter Register #define WPG_I2CSTAT_OFFSET 0x70 // I2C Status Register //---------------------------------------------------------------------------- // Winnipeg Store Type commands (Add this commands to the register offset) //---------------------------------------------------------------------------- #define WPG_I2C_AND 0x1000 // I2C AND operation #define WPG_I2C_OR 0x2000 // I2C OR operation //---------------------------------------------------------------------------- // Command set for I2C Master Operation Setup Register //---------------------------------------------------------------------------- #define WPG_READATADDR_MASK 0x00010000 // read,bytes,I2C shifted,index #define WPG_WRITEATADDR_MASK 0x40010000 // write,bytes,I2C shifted,index #define WPG_READDIRECT_MASK 0x10010000 #define WPG_WRITEDIRECT_MASK 0x60010000 //---------------------------------------------------------------------------- // bit masks for I2C Master Control Register //---------------------------------------------------------------------------- #define WPG_I2CMCNTL_STARTOP_MASK 0x00000002 // Start the Operation //---------------------------------------------------------------------------- // //---------------------------------------------------------------------------- #define WPG_I2C_IOREMAP_SIZE 0x2044 // size of linear address interval //---------------------------------------------------------------------------- // command index //---------------------------------------------------------------------------- #define WPG_1ST_SLOT_INDEX 0x01 // index - 1st slot for ctlr #define WPG_CTLR_INDEX 0x0F // index - ctlr #define WPG_1ST_EXTSLOT_INDEX 0x10 // index - 1st ext slot for ctlr #define WPG_1ST_BUS_INDEX 0x1F // index - 1st bus for ctlr //---------------------------------------------------------------------------- // macro utilities //---------------------------------------------------------------------------- // if bits 20,22,25,26,27,29,30 are OFF return 1 #define HPC_I2CSTATUS_CHECK(s) ((u8)((s & 0x00000A76) ? 0 : 1)) //---------------------------------------------------------------------------- // global variables //---------------------------------------------------------------------------- static struct mutex sem_hpcaccess; // lock access to HPC static struct semaphore semOperations; // lock all operations and // access to data structures static struct semaphore sem_exit; // make sure polling thread goes away static struct task_struct *ibmphp_poll_thread; //---------------------------------------------------------------------------- // local function prototypes //---------------------------------------------------------------------------- static u8 i2c_ctrl_read (struct controller *, void __iomem *, u8); static u8 i2c_ctrl_write (struct controller *, void __iomem *, u8, u8); static u8 hpc_writecmdtoindex (u8, u8); static u8 hpc_readcmdtoindex (u8, u8); static void get_hpc_access (void); static void free_hpc_access (void); static int poll_hpc(void *data); static int process_changeinstatus (struct slot *, struct slot *); static int process_changeinlatch (u8, u8, struct controller *); static int hpc_wait_ctlr_notworking (int, struct controller *, void __iomem *, u8 *); //---------------------------------------------------------------------------- /*---------------------------------------------------------------------- * Name: ibmphp_hpc_initvars * * Action: initialize semaphores and variables *---------------------------------------------------------------------*/ void __init ibmphp_hpc_initvars (void) { debug ("%s - Entry\n", __func__); mutex_init(&sem_hpcaccess); sema_init(&semOperations, 1); sema_init(&sem_exit, 0); to_debug = 0; debug ("%s - Exit\n", __func__); } /*---------------------------------------------------------------------- * Name: i2c_ctrl_read * * Action: read from HPC over I2C * *---------------------------------------------------------------------*/ static u8 i2c_ctrl_read (struct controller *ctlr_ptr, void __iomem *WPGBbar, u8 index) { u8 status; int i; void __iomem *wpg_addr; // base addr + offset unsigned long wpg_data; // data to/from WPG LOHI format unsigned long ultemp; unsigned long data; // actual data HILO format debug_polling ("%s - Entry WPGBbar[%p] index[%x] \n", __func__, WPGBbar, index); //-------------------------------------------------------------------- // READ - step 1 // read at address, byte length, I2C address (shifted), index // or read direct, byte length, index if (ctlr_ptr->ctlr_type == 0x02) { data = WPG_READATADDR_MASK; // fill in I2C address ultemp = (unsigned long)ctlr_ptr->u.wpeg_ctlr.i2c_addr; ultemp = ultemp >> 1; data |= (ultemp << 8); // fill in index data |= (unsigned long)index; } else if (ctlr_ptr->ctlr_type == 0x04) { data = WPG_READDIRECT_MASK; // fill in index ultemp = (unsigned long)index; ultemp = ultemp << 8; data |= ultemp; } else { err ("this controller type is not supported \n"); return HPC_ERROR; } wpg_data = swab32 (data); // swap data before writing wpg_addr = WPGBbar + WPG_I2CMOSUP_OFFSET; writel (wpg_data, wpg_addr); //-------------------------------------------------------------------- // READ - step 2 : clear the message buffer data = 0x00000000; wpg_data = swab32 (data); wpg_addr = WPGBbar + WPG_I2CMBUFL_OFFSET; writel (wpg_data, wpg_addr); //-------------------------------------------------------------------- // READ - step 3 : issue start operation, I2C master control bit 30:ON // 2020 : [20] OR operation at [20] offset 0x20 data = WPG_I2CMCNTL_STARTOP_MASK; wpg_data = swab32 (data); wpg_addr = WPGBbar + WPG_I2CMCNTL_OFFSET + WPG_I2C_OR; writel (wpg_data, wpg_addr); //-------------------------------------------------------------------- // READ - step 4 : wait until start operation bit clears i = CMD_COMPLETE_TOUT_SEC; while (i) { msleep(10); wpg_addr = WPGBbar + WPG_I2CMCNTL_OFFSET; wpg_data = readl (wpg_addr); data = swab32 (wpg_data); if (!(data & WPG_I2CMCNTL_STARTOP_MASK)) break; i--; } if (i == 0) { debug ("%s - Error : WPG timeout\n", __func__); return HPC_ERROR; } //-------------------------------------------------------------------- // READ - step 5 : read I2C status register i = CMD_COMPLETE_TOUT_SEC; while (i) { msleep(10); wpg_addr = WPGBbar + WPG_I2CSTAT_OFFSET; wpg_data = readl (wpg_addr); data = swab32 (wpg_data); if (HPC_I2CSTATUS_CHECK (data)) break; i--; } if (i == 0) { debug ("ctrl_read - Exit Error:I2C timeout\n"); return HPC_ERROR; } //-------------------------------------------------------------------- // READ - step 6 : get DATA wpg_addr = WPGBbar + WPG_I2CMBUFL_OFFSET; wpg_data = readl (wpg_addr); data = swab32 (wpg_data); status = (u8) data; debug_polling ("%s - Exit index[%x] status[%x]\n", __func__, index, status); return (status); } /*---------------------------------------------------------------------- * Name: i2c_ctrl_write * * Action: write to HPC over I2C * * Return 0 or error codes *---------------------------------------------------------------------*/ static u8 i2c_ctrl_write (struct controller *ctlr_ptr, void __iomem *WPGBbar, u8 index, u8 cmd) { u8 rc; void __iomem *wpg_addr; // base addr + offset unsigned long wpg_data; // data to/from WPG LOHI format unsigned long ultemp; unsigned long data; // actual data HILO format int i; debug_polling ("%s - Entry WPGBbar[%p] index[%x] cmd[%x]\n", __func__, WPGBbar, index, cmd); rc = 0; //-------------------------------------------------------------------- // WRITE - step 1 // write at address, byte length, I2C address (shifted), index // or write direct, byte length, index data = 0x00000000; if (ctlr_ptr->ctlr_type == 0x02) { data = WPG_WRITEATADDR_MASK; // fill in I2C address ultemp = (unsigned long)ctlr_ptr->u.wpeg_ctlr.i2c_addr; ultemp = ultemp >> 1; data |= (ultemp << 8); // fill in index data |= (unsigned long)index; } else if (ctlr_ptr->ctlr_type == 0x04) { data = WPG_WRITEDIRECT_MASK; // fill in index ultemp = (unsigned long)index; ultemp = ultemp << 8; data |= ultemp; } else { err ("this controller type is not supported \n"); return HPC_ERROR; } wpg_data = swab32 (data); // swap data before writing wpg_addr = WPGBbar + WPG_I2CMOSUP_OFFSET; writel (wpg_data, wpg_addr); //-------------------------------------------------------------------- // WRITE - step 2 : clear the message buffer data = 0x00000000 | (unsigned long)cmd; wpg_data = swab32 (data); wpg_addr = WPGBbar + WPG_I2CMBUFL_OFFSET; writel (wpg_data, wpg_addr); //-------------------------------------------------------------------- // WRITE - step 3 : issue start operation,I2C master control bit 30:ON // 2020 : [20] OR operation at [20] offset 0x20 data = WPG_I2CMCNTL_STARTOP_MASK; wpg_data = swab32 (data); wpg_addr = WPGBbar + WPG_I2CMCNTL_OFFSET + WPG_I2C_OR; writel (wpg_data, wpg_addr); //-------------------------------------------------------------------- // WRITE - step 4 : wait until start operation bit clears i = CMD_COMPLETE_TOUT_SEC; while (i) { msleep(10); wpg_addr = WPGBbar + WPG_I2CMCNTL_OFFSET; wpg_data = readl (wpg_addr); data = swab32 (wpg_data); if (!(data & WPG_I2CMCNTL_STARTOP_MASK)) break; i--; } if (i == 0) { debug ("%s - Exit Error:WPG timeout\n", __func__); rc = HPC_ERROR; } //-------------------------------------------------------------------- // WRITE - step 5 : read I2C status register i = CMD_COMPLETE_TOUT_SEC; while (i) { msleep(10); wpg_addr = WPGBbar + WPG_I2CSTAT_OFFSET; wpg_data = readl (wpg_addr); data = swab32 (wpg_data); if (HPC_I2CSTATUS_CHECK (data)) break; i--; } if (i == 0) { debug ("ctrl_read - Error : I2C timeout\n"); rc = HPC_ERROR; } debug_polling ("%s Exit rc[%x]\n", __func__, rc); return (rc); } //------------------------------------------------------------ // Read from ISA type HPC //------------------------------------------------------------ static u8 isa_ctrl_read (struct controller *ctlr_ptr, u8 offset) { u16 start_address; u16 end_address; u8 data; start_address = ctlr_ptr->u.isa_ctlr.io_start; end_address = ctlr_ptr->u.isa_ctlr.io_end; data = inb (start_address + offset); return data; } //-------------------------------------------------------------- // Write to ISA type HPC //-------------------------------------------------------------- static void isa_ctrl_write (struct controller *ctlr_ptr, u8 offset, u8 data) { u16 start_address; u16 port_address; start_address = ctlr_ptr->u.isa_ctlr.io_start; port_address = start_address + (u16) offset; outb (data, port_address); } static u8 pci_ctrl_read (struct controller *ctrl, u8 offset) { u8 data = 0x00; debug ("inside pci_ctrl_read\n"); if (ctrl->ctrl_dev) pci_read_config_byte (ctrl->ctrl_dev, HPC_PCI_OFFSET + offset, &data); return data; } static u8 pci_ctrl_write (struct controller *ctrl, u8 offset, u8 data) { u8 rc = -ENODEV; debug ("inside pci_ctrl_write\n"); if (ctrl->ctrl_dev) { pci_write_config_byte (ctrl->ctrl_dev, HPC_PCI_OFFSET + offset, data); rc = 0; } return rc; } static u8 ctrl_read (struct controller *ctlr, void __iomem *base, u8 offset) { u8 rc; switch (ctlr->ctlr_type) { case 0: rc = isa_ctrl_read (ctlr, offset); break; case 1: rc = pci_ctrl_read (ctlr, offset); break; case 2: case 4: rc = i2c_ctrl_read (ctlr, base, offset); break; default: return -ENODEV; } return rc; } static u8 ctrl_write (struct controller *ctlr, void __iomem *base, u8 offset, u8 data) { u8 rc = 0; switch (ctlr->ctlr_type) { case 0: isa_ctrl_write(ctlr, offset, data); break; case 1: rc = pci_ctrl_write (ctlr, offset, data); break; case 2: case 4: rc = i2c_ctrl_write(ctlr, base, offset, data); break; default: return -ENODEV; } return rc; } /*---------------------------------------------------------------------- * Name: hpc_writecmdtoindex() * * Action: convert a write command to proper index within a controller * * Return index, HPC_ERROR *---------------------------------------------------------------------*/ static u8 hpc_writecmdtoindex (u8 cmd, u8 index) { u8 rc; switch (cmd) { case HPC_CTLR_ENABLEIRQ: // 0x00.N.15 case HPC_CTLR_CLEARIRQ: // 0x06.N.15 case HPC_CTLR_RESET: // 0x07.N.15 case HPC_CTLR_IRQSTEER: // 0x08.N.15 case HPC_CTLR_DISABLEIRQ: // 0x01.N.15 case HPC_ALLSLOT_ON: // 0x11.N.15 case HPC_ALLSLOT_OFF: // 0x12.N.15 rc = 0x0F; break; case HPC_SLOT_OFF: // 0x02.Y.0-14 case HPC_SLOT_ON: // 0x03.Y.0-14 case HPC_SLOT_ATTNOFF: // 0x04.N.0-14 case HPC_SLOT_ATTNON: // 0x05.N.0-14 case HPC_SLOT_BLINKLED: // 0x13.N.0-14 rc = index; break; case HPC_BUS_33CONVMODE: case HPC_BUS_66CONVMODE: case HPC_BUS_66PCIXMODE: case HPC_BUS_100PCIXMODE: case HPC_BUS_133PCIXMODE: rc = index + WPG_1ST_BUS_INDEX - 1; break; default: err ("hpc_writecmdtoindex - Error invalid cmd[%x]\n", cmd); rc = HPC_ERROR; } return rc; } /*---------------------------------------------------------------------- * Name: hpc_readcmdtoindex() * * Action: convert a read command to proper index within a controller * * Return index, HPC_ERROR *---------------------------------------------------------------------*/ static u8 hpc_readcmdtoindex (u8 cmd, u8 index) { u8 rc; switch (cmd) { case READ_CTLRSTATUS: rc = 0x0F; break; case READ_SLOTSTATUS: case READ_ALLSTAT: rc = index; break; case READ_EXTSLOTSTATUS: rc = index + WPG_1ST_EXTSLOT_INDEX; break; case READ_BUSSTATUS: rc = index + WPG_1ST_BUS_INDEX - 1; break; case READ_SLOTLATCHLOWREG: rc = 0x28; break; case READ_REVLEVEL: rc = 0x25; break; case READ_HPCOPTIONS: rc = 0x27; break; default: rc = HPC_ERROR; } return rc; } /*---------------------------------------------------------------------- * Name: HPCreadslot() * * Action: issue a READ command to HPC * * Input: pslot - cannot be NULL for READ_ALLSTAT * pstatus - can be NULL for READ_ALLSTAT * * Return 0 or error codes *---------------------------------------------------------------------*/ int ibmphp_hpc_readslot (struct slot * pslot, u8 cmd, u8 * pstatus) { void __iomem *wpg_bbar = NULL; struct controller *ctlr_ptr; struct list_head *pslotlist; u8 index, status; int rc = 0; int busindex; debug_polling ("%s - Entry pslot[%p] cmd[%x] pstatus[%p]\n", __func__, pslot, cmd, pstatus); if ((pslot == NULL) || ((pstatus == NULL) && (cmd != READ_ALLSTAT) && (cmd != READ_BUSSTATUS))) { rc = -EINVAL; err ("%s - Error invalid pointer, rc[%d]\n", __func__, rc); return rc; } if (cmd == READ_BUSSTATUS) { busindex = ibmphp_get_bus_index (pslot->bus); if (busindex < 0) { rc = -EINVAL; err ("%s - Exit Error:invalid bus, rc[%d]\n", __func__, rc); return rc; } else index = (u8) busindex; } else index = pslot->ctlr_index; index = hpc_readcmdtoindex (cmd, index); if (index == HPC_ERROR) { rc = -EINVAL; err ("%s - Exit Error:invalid index, rc[%d]\n", __func__, rc); return rc; } ctlr_ptr = pslot->ctrl; get_hpc_access (); //-------------------------------------------------------------------- // map physical address to logical address //-------------------------------------------------------------------- if ((ctlr_ptr->ctlr_type == 2) || (ctlr_ptr->ctlr_type == 4)) wpg_bbar = ioremap (ctlr_ptr->u.wpeg_ctlr.wpegbbar, WPG_I2C_IOREMAP_SIZE); //-------------------------------------------------------------------- // check controller status before reading //-------------------------------------------------------------------- rc = hpc_wait_ctlr_notworking (HPC_CTLR_WORKING_TOUT, ctlr_ptr, wpg_bbar, &status); if (!rc) { switch (cmd) { case READ_ALLSTAT: // update the slot structure pslot->ctrl->status = status; pslot->status = ctrl_read (ctlr_ptr, wpg_bbar, index); rc = hpc_wait_ctlr_notworking (HPC_CTLR_WORKING_TOUT, ctlr_ptr, wpg_bbar, &status); if (!rc) pslot->ext_status = ctrl_read (ctlr_ptr, wpg_bbar, index + WPG_1ST_EXTSLOT_INDEX); break; case READ_SLOTSTATUS: // DO NOT update the slot structure *pstatus = ctrl_read (ctlr_ptr, wpg_bbar, index); break; case READ_EXTSLOTSTATUS: // DO NOT update the slot structure *pstatus = ctrl_read (ctlr_ptr, wpg_bbar, index); break; case READ_CTLRSTATUS: // DO NOT update the slot structure *pstatus = status; break; case READ_BUSSTATUS: pslot->busstatus = ctrl_read (ctlr_ptr, wpg_bbar, index); break; case READ_REVLEVEL: *pstatus = ctrl_read (ctlr_ptr, wpg_bbar, index); break; case READ_HPCOPTIONS: *pstatus = ctrl_read (ctlr_ptr, wpg_bbar, index); break; case READ_SLOTLATCHLOWREG: // DO NOT update the slot structure *pstatus = ctrl_read (ctlr_ptr, wpg_bbar, index); break; // Not used case READ_ALLSLOT: list_for_each (pslotlist, &ibmphp_slot_head) { pslot = list_entry (pslotlist, struct slot, ibm_slot_list); index = pslot->ctlr_index; rc = hpc_wait_ctlr_notworking (HPC_CTLR_WORKING_TOUT, ctlr_ptr, wpg_bbar, &status); if (!rc) { pslot->status = ctrl_read (ctlr_ptr, wpg_bbar, index); rc = hpc_wait_ctlr_notworking (HPC_CTLR_WORKING_TOUT, ctlr_ptr, wpg_bbar, &status); if (!rc) pslot->ext_status = ctrl_read (ctlr_ptr, wpg_bbar, index + WPG_1ST_EXTSLOT_INDEX); } else { err ("%s - Error ctrl_read failed\n", __func__); rc = -EINVAL; break; } } break; default: rc = -EINVAL; break; } } //-------------------------------------------------------------------- // cleanup //-------------------------------------------------------------------- // remove physical to logical address mapping if ((ctlr_ptr->ctlr_type == 2) || (ctlr_ptr->ctlr_type == 4)) iounmap (wpg_bbar); free_hpc_access (); debug_polling ("%s - Exit rc[%d]\n", __func__, rc); return rc; } /*---------------------------------------------------------------------- * Name: ibmphp_hpc_writeslot() * * Action: issue a WRITE command to HPC *---------------------------------------------------------------------*/ int ibmphp_hpc_writeslot (struct slot * pslot, u8 cmd) { void __iomem *wpg_bbar = NULL; struct controller *ctlr_ptr; u8 index, status; int busindex; u8 done; int rc = 0; int timeout; debug_polling ("%s - Entry pslot[%p] cmd[%x]\n", __func__, pslot, cmd); if (pslot == NULL) { rc = -EINVAL; err ("%s - Error Exit rc[%d]\n", __func__, rc); return rc; } if ((cmd == HPC_BUS_33CONVMODE) || (cmd == HPC_BUS_66CONVMODE) || (cmd == HPC_BUS_66PCIXMODE) || (cmd == HPC_BUS_100PCIXMODE) || (cmd == HPC_BUS_133PCIXMODE)) { busindex = ibmphp_get_bus_index (pslot->bus); if (busindex < 0) { rc = -EINVAL; err ("%s - Exit Error:invalid bus, rc[%d]\n", __func__, rc); return rc; } else index = (u8) busindex; } else index = pslot->ctlr_index; index = hpc_writecmdtoindex (cmd, index); if (index == HPC_ERROR) { rc = -EINVAL; err ("%s - Error Exit rc[%d]\n", __func__, rc); return rc; } ctlr_ptr = pslot->ctrl; get_hpc_access (); //-------------------------------------------------------------------- // map physical address to logical address //-------------------------------------------------------------------- if ((ctlr_ptr->ctlr_type == 2) || (ctlr_ptr->ctlr_type == 4)) { wpg_bbar = ioremap (ctlr_ptr->u.wpeg_ctlr.wpegbbar, WPG_I2C_IOREMAP_SIZE); debug ("%s - ctlr id[%x] physical[%lx] logical[%lx] i2c[%x]\n", __func__, ctlr_ptr->ctlr_id, (ulong) (ctlr_ptr->u.wpeg_ctlr.wpegbbar), (ulong) wpg_bbar, ctlr_ptr->u.wpeg_ctlr.i2c_addr); } //-------------------------------------------------------------------- // check controller status before writing //-------------------------------------------------------------------- rc = hpc_wait_ctlr_notworking (HPC_CTLR_WORKING_TOUT, ctlr_ptr, wpg_bbar, &status); if (!rc) { ctrl_write (ctlr_ptr, wpg_bbar, index, cmd); //-------------------------------------------------------------------- // check controller is still not working on the command //-------------------------------------------------------------------- timeout = CMD_COMPLETE_TOUT_SEC; done = 0; while (!done) { rc = hpc_wait_ctlr_notworking (HPC_CTLR_WORKING_TOUT, ctlr_ptr, wpg_bbar, &status); if (!rc) { if (NEEDTOCHECK_CMDSTATUS (cmd)) { if (CTLR_FINISHED (status) == HPC_CTLR_FINISHED_YES) done = 1; } else done = 1; } if (!done) { msleep(1000); if (timeout < 1) { done = 1; err ("%s - Error command complete timeout\n", __func__); rc = -EFAULT; } else timeout--; } } ctlr_ptr->status = status; } // cleanup // remove physical to logical address mapping if ((ctlr_ptr->ctlr_type == 2) || (ctlr_ptr->ctlr_type == 4)) iounmap (wpg_bbar); free_hpc_access (); debug_polling ("%s - Exit rc[%d]\n", __func__, rc); return rc; } /*---------------------------------------------------------------------- * Name: get_hpc_access() * * Action: make sure only one process can access HPC at one time *---------------------------------------------------------------------*/ static void get_hpc_access (void) { mutex_lock(&sem_hpcaccess); } /*---------------------------------------------------------------------- * Name: free_hpc_access() *---------------------------------------------------------------------*/ void free_hpc_access (void) { mutex_unlock(&sem_hpcaccess); } /*---------------------------------------------------------------------- * Name: ibmphp_lock_operations() * * Action: make sure only one process can change the data structure *---------------------------------------------------------------------*/ void ibmphp_lock_operations (void) { down (&semOperations); to_debug = 1; } /*---------------------------------------------------------------------- * Name: ibmphp_unlock_operations() *---------------------------------------------------------------------*/ void ibmphp_unlock_operations (void) { debug ("%s - Entry\n", __func__); up (&semOperations); to_debug = 0; debug ("%s - Exit\n", __func__); } /*---------------------------------------------------------------------- * Name: poll_hpc() *---------------------------------------------------------------------*/ #define POLL_LATCH_REGISTER 0 #define POLL_SLOTS 1 #define POLL_SLEEP 2 static int poll_hpc(void *data) { struct slot myslot; struct slot *pslot = NULL; struct list_head *pslotlist; int rc; int poll_state = POLL_LATCH_REGISTER; u8 oldlatchlow = 0x00; u8 curlatchlow = 0x00; int poll_count = 0; u8 ctrl_count = 0x00; debug ("%s - Entry\n", __func__); while (!kthread_should_stop()) { /* try to get the lock to do some kind of hardware access */ down (&semOperations); switch (poll_state) { case POLL_LATCH_REGISTER: oldlatchlow = curlatchlow; ctrl_count = 0x00; list_for_each (pslotlist, &ibmphp_slot_head) { if (ctrl_count >= ibmphp_get_total_controllers()) break; pslot = list_entry (pslotlist, struct slot, ibm_slot_list); if (pslot->ctrl->ctlr_relative_id == ctrl_count) { ctrl_count++; if (READ_SLOT_LATCH (pslot->ctrl)) { rc = ibmphp_hpc_readslot (pslot, READ_SLOTLATCHLOWREG, &curlatchlow); if (oldlatchlow != curlatchlow) process_changeinlatch (oldlatchlow, curlatchlow, pslot->ctrl); } } } ++poll_count; poll_state = POLL_SLEEP; break; case POLL_SLOTS: list_for_each (pslotlist, &ibmphp_slot_head) { pslot = list_entry (pslotlist, struct slot, ibm_slot_list); // make a copy of the old status memcpy ((void *) &myslot, (void *) pslot, sizeof (struct slot)); rc = ibmphp_hpc_readslot (pslot, READ_ALLSTAT, NULL); if ((myslot.status != pslot->status) || (myslot.ext_status != pslot->ext_status)) process_changeinstatus (pslot, &myslot); } ctrl_count = 0x00; list_for_each (pslotlist, &ibmphp_slot_head) { if (ctrl_count >= ibmphp_get_total_controllers()) break; pslot = list_entry (pslotlist, struct slot, ibm_slot_list); if (pslot->ctrl->ctlr_relative_id == ctrl_count) { ctrl_count++; if (READ_SLOT_LATCH (pslot->ctrl)) rc = ibmphp_hpc_readslot (pslot, READ_SLOTLATCHLOWREG, &curlatchlow); } } ++poll_count; poll_state = POLL_SLEEP; break; case POLL_SLEEP: /* don't sleep with a lock on the hardware */ up (&semOperations); msleep(POLL_INTERVAL_SEC * 1000); if (kthread_should_stop()) goto out_sleep; down (&semOperations); if (poll_count >= POLL_LATCH_CNT) { poll_count = 0; poll_state = POLL_SLOTS; } else poll_state = POLL_LATCH_REGISTER; break; } /* give up the hardware semaphore */ up (&semOperations); /* sleep for a short time just for good measure */ out_sleep: msleep(100); } up (&sem_exit); debug ("%s - Exit\n", __func__); return 0; } /*---------------------------------------------------------------------- * Name: process_changeinstatus * * Action: compare old and new slot status, process the change in status * * Input: pointer to slot struct, old slot struct * * Return 0 or error codes * Value: * * Side * Effects: None. * * Notes: *---------------------------------------------------------------------*/ static int process_changeinstatus (struct slot *pslot, struct slot *poldslot) { u8 status; int rc = 0; u8 disable = 0; u8 update = 0; debug ("process_changeinstatus - Entry pslot[%p], poldslot[%p]\n", pslot, poldslot); // bit 0 - HPC_SLOT_POWER if ((pslot->status & 0x01) != (poldslot->status & 0x01)) update = 1; // bit 1 - HPC_SLOT_CONNECT // ignore // bit 2 - HPC_SLOT_ATTN if ((pslot->status & 0x04) != (poldslot->status & 0x04)) update = 1; // bit 3 - HPC_SLOT_PRSNT2 // bit 4 - HPC_SLOT_PRSNT1 if (((pslot->status & 0x08) != (poldslot->status & 0x08)) || ((pslot->status & 0x10) != (poldslot->status & 0x10))) update = 1; // bit 5 - HPC_SLOT_PWRGD if ((pslot->status & 0x20) != (poldslot->status & 0x20)) // OFF -> ON: ignore, ON -> OFF: disable slot if ((poldslot->status & 0x20) && (SLOT_CONNECT (poldslot->status) == HPC_SLOT_CONNECTED) && (SLOT_PRESENT (poldslot->status))) disable = 1; // bit 6 - HPC_SLOT_BUS_SPEED // ignore // bit 7 - HPC_SLOT_LATCH if ((pslot->status & 0x80) != (poldslot->status & 0x80)) { update = 1; // OPEN -> CLOSE if (pslot->status & 0x80) { if (SLOT_PWRGD (pslot->status)) { // power goes on and off after closing latch // check again to make sure power is still ON msleep(1000); rc = ibmphp_hpc_readslot (pslot, READ_SLOTSTATUS, &status); if (SLOT_PWRGD (status)) update = 1; else // overwrite power in pslot to OFF pslot->status &= ~HPC_SLOT_POWER; } } // CLOSE -> OPEN else if ((SLOT_PWRGD (poldslot->status) == HPC_SLOT_PWRGD_GOOD) && (SLOT_CONNECT (poldslot->status) == HPC_SLOT_CONNECTED) && (SLOT_PRESENT (poldslot->status))) { disable = 1; } // else - ignore } // bit 4 - HPC_SLOT_BLINK_ATTN if ((pslot->ext_status & 0x08) != (poldslot->ext_status & 0x08)) update = 1; if (disable) { debug ("process_changeinstatus - disable slot\n"); pslot->flag = 0; rc = ibmphp_do_disable_slot (pslot); } if (update || disable) { ibmphp_update_slot_info (pslot); } debug ("%s - Exit rc[%d] disable[%x] update[%x]\n", __func__, rc, disable, update); return rc; } /*---------------------------------------------------------------------- * Name: process_changeinlatch * * Action: compare old and new latch reg status, process the change * * Input: old and current latch register status * * Return 0 or error codes * Value: *---------------------------------------------------------------------*/ static int process_changeinlatch (u8 old, u8 new, struct controller *ctrl) { struct slot myslot, *pslot; u8 i; u8 mask; int rc = 0; debug ("%s - Entry old[%x], new[%x]\n", __func__, old, new); // bit 0 reserved, 0 is LSB, check bit 1-6 for 6 slots for (i = ctrl->starting_slot_num; i <= ctrl->ending_slot_num; i++) { mask = 0x01 << i; if ((mask & old) != (mask & new)) { pslot = ibmphp_get_slot_from_physical_num (i); if (pslot) { memcpy ((void *) &myslot, (void *) pslot, sizeof (struct slot)); rc = ibmphp_hpc_readslot (pslot, READ_ALLSTAT, NULL); debug ("%s - call process_changeinstatus for slot[%d]\n", __func__, i); process_changeinstatus (pslot, &myslot); } else { rc = -EINVAL; err ("%s - Error bad pointer for slot[%d]\n", __func__, i); } } } debug ("%s - Exit rc[%d]\n", __func__, rc); return rc; } /*---------------------------------------------------------------------- * Name: ibmphp_hpc_start_poll_thread * * Action: start polling thread *---------------------------------------------------------------------*/ int __init ibmphp_hpc_start_poll_thread (void) { debug ("%s - Entry\n", __func__); ibmphp_poll_thread = kthread_run(poll_hpc, NULL, "hpc_poll"); if (IS_ERR(ibmphp_poll_thread)) { err ("%s - Error, thread not started\n", __func__); return PTR_ERR(ibmphp_poll_thread); } return 0; } /*---------------------------------------------------------------------- * Name: ibmphp_hpc_stop_poll_thread * * Action: stop polling thread and cleanup *---------------------------------------------------------------------*/ void __exit ibmphp_hpc_stop_poll_thread (void) { debug ("%s - Entry\n", __func__); kthread_stop(ibmphp_poll_thread); debug ("before locking operations \n"); ibmphp_lock_operations (); debug ("after locking operations \n"); // wait for poll thread to exit debug ("before sem_exit down \n"); down (&sem_exit); debug ("after sem_exit down \n"); // cleanup debug ("before free_hpc_access \n"); free_hpc_access (); debug ("after free_hpc_access \n"); ibmphp_unlock_operations (); debug ("after unlock operations \n"); up (&sem_exit); debug ("after sem exit up\n"); debug ("%s - Exit\n", __func__); } /*---------------------------------------------------------------------- * Name: hpc_wait_ctlr_notworking * * Action: wait until the controller is in a not working state * * Return 0, HPC_ERROR * Value: *---------------------------------------------------------------------*/ static int hpc_wait_ctlr_notworking (int timeout, struct controller *ctlr_ptr, void __iomem *wpg_bbar, u8 * pstatus) { int rc = 0; u8 done = 0; debug_polling ("hpc_wait_ctlr_notworking - Entry timeout[%d]\n", timeout); while (!done) { *pstatus = ctrl_read (ctlr_ptr, wpg_bbar, WPG_CTLR_INDEX); if (*pstatus == HPC_ERROR) { rc = HPC_ERROR; done = 1; } if (CTLR_WORKING (*pstatus) == HPC_CTLR_WORKING_NO) done = 1; if (!done) { msleep(1000); if (timeout < 1) { done = 1; err ("HPCreadslot - Error ctlr timeout\n"); rc = HPC_ERROR; } else timeout--; } } debug_polling ("hpc_wait_ctlr_notworking - Exit rc[%x] status[%x]\n", rc, *pstatus); return rc; }