// SPDX-License-Identifier: GPL-2.0-or-later /* * Freescale MPC85xx/MPC86xx RapidIO RMU support * * Copyright 2009 Sysgo AG * Thomas Moll <thomas.moll@sysgo.com> * - fixed maintenance access routines, check for aligned access * * Copyright 2009 Integrated Device Technology, Inc. * Alex Bounine <alexandre.bounine@idt.com> * - Added Port-Write message handling * - Added Machine Check exception handling * * Copyright (C) 2007, 2008, 2010, 2011 Freescale Semiconductor, Inc. * Zhang Wei <wei.zhang@freescale.com> * Lian Minghuan-B31939 <Minghuan.Lian@freescale.com> * Liu Gang <Gang.Liu@freescale.com> * * Copyright 2005 MontaVista Software, Inc. * Matt Porter <mporter@kernel.crashing.org> */ #include <linux/types.h> #include <linux/dma-mapping.h> #include <linux/interrupt.h> #include <linux/of_address.h> #include <linux/of_irq.h> #include <linux/slab.h> #include "fsl_rio.h" #define GET_RMM_HANDLE(mport) \ (((struct rio_priv *)(mport->priv))->rmm_handle) /* RapidIO definition irq, which read from OF-tree */ #define IRQ_RIO_PW(m) (((struct fsl_rio_pw *)(m))->pwirq) #define IRQ_RIO_BELL(m) (((struct fsl_rio_dbell *)(m))->bellirq) #define IRQ_RIO_TX(m) (((struct fsl_rmu *)(GET_RMM_HANDLE(m)))->txirq) #define IRQ_RIO_RX(m) (((struct fsl_rmu *)(GET_RMM_HANDLE(m)))->rxirq) #define RIO_MIN_TX_RING_SIZE 2 #define RIO_MAX_TX_RING_SIZE 2048 #define RIO_MIN_RX_RING_SIZE 2 #define RIO_MAX_RX_RING_SIZE 2048 #define RIO_IPWMR_SEN 0x00100000 #define RIO_IPWMR_QFIE 0x00000100 #define RIO_IPWMR_EIE 0x00000020 #define RIO_IPWMR_CQ 0x00000002 #define RIO_IPWMR_PWE 0x00000001 #define RIO_IPWSR_QF 0x00100000 #define RIO_IPWSR_TE 0x00000080 #define RIO_IPWSR_QFI 0x00000010 #define RIO_IPWSR_PWD 0x00000008 #define RIO_IPWSR_PWB 0x00000004 #define RIO_EPWISR 0x10010 /* EPWISR Error match value */ #define RIO_EPWISR_PINT1 0x80000000 #define RIO_EPWISR_PINT2 0x40000000 #define RIO_EPWISR_MU 0x00000002 #define RIO_EPWISR_PW 0x00000001 #define IPWSR_CLEAR 0x98 #define OMSR_CLEAR 0x1cb3 #define IMSR_CLEAR 0x491 #define IDSR_CLEAR 0x91 #define ODSR_CLEAR 0x1c00 #define LTLEECSR_ENABLE_ALL 0xFFC000FC #define RIO_LTLEECSR 0x060c #define RIO_IM0SR 0x64 #define RIO_IM1SR 0x164 #define RIO_OM0SR 0x4 #define RIO_OM1SR 0x104 #define RIO_DBELL_WIN_SIZE 0x1000 #define RIO_MSG_OMR_MUI 0x00000002 #define RIO_MSG_OSR_TE 0x00000080 #define RIO_MSG_OSR_QOI 0x00000020 #define RIO_MSG_OSR_QFI 0x00000010 #define RIO_MSG_OSR_MUB 0x00000004 #define RIO_MSG_OSR_EOMI 0x00000002 #define RIO_MSG_OSR_QEI 0x00000001 #define RIO_MSG_IMR_MI 0x00000002 #define RIO_MSG_ISR_TE 0x00000080 #define RIO_MSG_ISR_QFI 0x00000010 #define RIO_MSG_ISR_DIQI 0x00000001 #define RIO_MSG_DESC_SIZE 32 #define RIO_MSG_BUFFER_SIZE 4096 #define DOORBELL_DMR_DI 0x00000002 #define DOORBELL_DSR_TE 0x00000080 #define DOORBELL_DSR_QFI 0x00000010 #define DOORBELL_DSR_DIQI 0x00000001 #define DOORBELL_MESSAGE_SIZE 0x08 static DEFINE_SPINLOCK(fsl_rio_doorbell_lock); struct rio_msg_regs { u32 omr; u32 osr; u32 pad1; u32 odqdpar; u32 pad2; u32 osar; u32 odpr; u32 odatr; u32 odcr; u32 pad3; u32 odqepar; u32 pad4[13]; u32 imr; u32 isr; u32 pad5; u32 ifqdpar; u32 pad6; u32 ifqepar; }; struct rio_dbell_regs { u32 odmr; u32 odsr; u32 pad1[4]; u32 oddpr; u32 oddatr; u32 pad2[3]; u32 odretcr; u32 pad3[12]; u32 dmr; u32 dsr; u32 pad4; u32 dqdpar; u32 pad5; u32 dqepar; }; struct rio_pw_regs { u32 pwmr; u32 pwsr; u32 epwqbar; u32 pwqbar; }; struct rio_tx_desc { u32 pad1; u32 saddr; u32 dport; u32 dattr; u32 pad2; u32 pad3; u32 dwcnt; u32 pad4; }; struct rio_msg_tx_ring { void *virt; dma_addr_t phys; void *virt_buffer[RIO_MAX_TX_RING_SIZE]; dma_addr_t phys_buffer[RIO_MAX_TX_RING_SIZE]; int tx_slot; int size; void *dev_id; }; struct rio_msg_rx_ring { void *virt; dma_addr_t phys; void *virt_buffer[RIO_MAX_RX_RING_SIZE]; int rx_slot; int size; void *dev_id; }; struct fsl_rmu { struct rio_msg_regs __iomem *msg_regs; struct rio_msg_tx_ring msg_tx_ring; struct rio_msg_rx_ring msg_rx_ring; int txirq; int rxirq; }; struct rio_dbell_msg { u16 pad1; u16 tid; u16 sid; u16 info; }; /** * fsl_rio_tx_handler - MPC85xx outbound message interrupt handler * @irq: Linux interrupt number * @dev_instance: Pointer to interrupt-specific data * * Handles outbound message interrupts. Executes a register outbound * mailbox event handler and acks the interrupt occurrence. */ static irqreturn_t fsl_rio_tx_handler(int irq, void *dev_instance) { int osr; struct rio_mport *port = (struct rio_mport *)dev_instance; struct fsl_rmu *rmu = GET_RMM_HANDLE(port); osr = in_be32(&rmu->msg_regs->osr); if (osr & RIO_MSG_OSR_TE) { pr_info("RIO: outbound message transmission error\n"); out_be32(&rmu->msg_regs->osr, RIO_MSG_OSR_TE); goto out; } if (osr & RIO_MSG_OSR_QOI) { pr_info("RIO: outbound message queue overflow\n"); out_be32(&rmu->msg_regs->osr, RIO_MSG_OSR_QOI); goto out; } if (osr & RIO_MSG_OSR_EOMI) { u32 dqp = in_be32(&rmu->msg_regs->odqdpar); int slot = (dqp - rmu->msg_tx_ring.phys) >> 5; if (port->outb_msg[0].mcback != NULL) { port->outb_msg[0].mcback(port, rmu->msg_tx_ring.dev_id, -1, slot); } /* Ack the end-of-message interrupt */ out_be32(&rmu->msg_regs->osr, RIO_MSG_OSR_EOMI); } out: return IRQ_HANDLED; } /** * fsl_rio_rx_handler - MPC85xx inbound message interrupt handler * @irq: Linux interrupt number * @dev_instance: Pointer to interrupt-specific data * * Handles inbound message interrupts. Executes a registered inbound * mailbox event handler and acks the interrupt occurrence. */ static irqreturn_t fsl_rio_rx_handler(int irq, void *dev_instance) { int isr; struct rio_mport *port = (struct rio_mport *)dev_instance; struct fsl_rmu *rmu = GET_RMM_HANDLE(port); isr = in_be32(&rmu->msg_regs->isr); if (isr & RIO_MSG_ISR_TE) { pr_info("RIO: inbound message reception error\n"); out_be32((void *)&rmu->msg_regs->isr, RIO_MSG_ISR_TE); goto out; } /* XXX Need to check/dispatch until queue empty */ if (isr & RIO_MSG_ISR_DIQI) { /* * Can receive messages for any mailbox/letter to that * mailbox destination. So, make the callback with an * unknown/invalid mailbox number argument. */ if (port->inb_msg[0].mcback != NULL) port->inb_msg[0].mcback(port, rmu->msg_rx_ring.dev_id, -1, -1); /* Ack the queueing interrupt */ out_be32(&rmu->msg_regs->isr, RIO_MSG_ISR_DIQI); } out: return IRQ_HANDLED; } /** * fsl_rio_dbell_handler - MPC85xx doorbell interrupt handler * @irq: Linux interrupt number * @dev_instance: Pointer to interrupt-specific data * * Handles doorbell interrupts. Parses a list of registered * doorbell event handlers and executes a matching event handler. */ static irqreturn_t fsl_rio_dbell_handler(int irq, void *dev_instance) { int dsr; struct fsl_rio_dbell *fsl_dbell = (struct fsl_rio_dbell *)dev_instance; int i; dsr = in_be32(&fsl_dbell->dbell_regs->dsr); if (dsr & DOORBELL_DSR_TE) { pr_info("RIO: doorbell reception error\n"); out_be32(&fsl_dbell->dbell_regs->dsr, DOORBELL_DSR_TE); goto out; } if (dsr & DOORBELL_DSR_QFI) { pr_info("RIO: doorbell queue full\n"); out_be32(&fsl_dbell->dbell_regs->dsr, DOORBELL_DSR_QFI); } /* XXX Need to check/dispatch until queue empty */ if (dsr & DOORBELL_DSR_DIQI) { struct rio_dbell_msg *dmsg = fsl_dbell->dbell_ring.virt + (in_be32(&fsl_dbell->dbell_regs->dqdpar) & 0xfff); struct rio_dbell *dbell; int found = 0; pr_debug ("RIO: processing doorbell," " sid %2.2x tid %2.2x info %4.4x\n", dmsg->sid, dmsg->tid, dmsg->info); for (i = 0; i < MAX_PORT_NUM; i++) { if (fsl_dbell->mport[i]) { list_for_each_entry(dbell, &fsl_dbell->mport[i]->dbells, node) { if ((dbell->res->start <= dmsg->info) && (dbell->res->end >= dmsg->info)) { found = 1; break; } } if (found && dbell->dinb) { dbell->dinb(fsl_dbell->mport[i], dbell->dev_id, dmsg->sid, dmsg->tid, dmsg->info); break; } } } if (!found) { pr_debug ("RIO: spurious doorbell," " sid %2.2x tid %2.2x info %4.4x\n", dmsg->sid, dmsg->tid, dmsg->info); } setbits32(&fsl_dbell->dbell_regs->dmr, DOORBELL_DMR_DI); out_be32(&fsl_dbell->dbell_regs->dsr, DOORBELL_DSR_DIQI); } out: return IRQ_HANDLED; } static void msg_unit_error_handler(void) { /*XXX: Error recovery is not implemented, we just clear errors */ out_be32((u32 *)(rio_regs_win + RIO_LTLEDCSR), 0); out_be32((u32 *)(rmu_regs_win + RIO_IM0SR), IMSR_CLEAR); out_be32((u32 *)(rmu_regs_win + RIO_IM1SR), IMSR_CLEAR); out_be32((u32 *)(rmu_regs_win + RIO_OM0SR), OMSR_CLEAR); out_be32((u32 *)(rmu_regs_win + RIO_OM1SR), OMSR_CLEAR); out_be32(&dbell->dbell_regs->odsr, ODSR_CLEAR); out_be32(&dbell->dbell_regs->dsr, IDSR_CLEAR); out_be32(&pw->pw_regs->pwsr, IPWSR_CLEAR); } /** * fsl_rio_port_write_handler - MPC85xx port write interrupt handler * @irq: Linux interrupt number * @dev_instance: Pointer to interrupt-specific data * * Handles port write interrupts. Parses a list of registered * port write event handlers and executes a matching event handler. */ static irqreturn_t fsl_rio_port_write_handler(int irq, void *dev_instance) { u32 ipwmr, ipwsr; struct fsl_rio_pw *pw = (struct fsl_rio_pw *)dev_instance; u32 epwisr, tmp; epwisr = in_be32(rio_regs_win + RIO_EPWISR); if (!(epwisr & RIO_EPWISR_PW)) goto pw_done; ipwmr = in_be32(&pw->pw_regs->pwmr); ipwsr = in_be32(&pw->pw_regs->pwsr); #ifdef DEBUG_PW pr_debug("PW Int->IPWMR: 0x%08x IPWSR: 0x%08x (", ipwmr, ipwsr); if (ipwsr & RIO_IPWSR_QF) pr_debug(" QF"); if (ipwsr & RIO_IPWSR_TE) pr_debug(" TE"); if (ipwsr & RIO_IPWSR_QFI) pr_debug(" QFI"); if (ipwsr & RIO_IPWSR_PWD) pr_debug(" PWD"); if (ipwsr & RIO_IPWSR_PWB) pr_debug(" PWB"); pr_debug(" )\n"); #endif /* Schedule deferred processing if PW was received */ if (ipwsr & RIO_IPWSR_QFI) { /* Save PW message (if there is room in FIFO), * otherwise discard it. */ if (kfifo_avail(&pw->pw_fifo) >= RIO_PW_MSG_SIZE) { pw->port_write_msg.msg_count++; kfifo_in(&pw->pw_fifo, pw->port_write_msg.virt, RIO_PW_MSG_SIZE); } else { pw->port_write_msg.discard_count++; pr_debug("RIO: ISR Discarded Port-Write Msg(s) (%d)\n", pw->port_write_msg.discard_count); } /* Clear interrupt and issue Clear Queue command. This allows * another port-write to be received. */ out_be32(&pw->pw_regs->pwsr, RIO_IPWSR_QFI); out_be32(&pw->pw_regs->pwmr, ipwmr | RIO_IPWMR_CQ); schedule_work(&pw->pw_work); } if ((ipwmr & RIO_IPWMR_EIE) && (ipwsr & RIO_IPWSR_TE)) { pw->port_write_msg.err_count++; pr_debug("RIO: Port-Write Transaction Err (%d)\n", pw->port_write_msg.err_count); /* Clear Transaction Error: port-write controller should be * disabled when clearing this error */ out_be32(&pw->pw_regs->pwmr, ipwmr & ~RIO_IPWMR_PWE); out_be32(&pw->pw_regs->pwsr, RIO_IPWSR_TE); out_be32(&pw->pw_regs->pwmr, ipwmr); } if (ipwsr & RIO_IPWSR_PWD) { pw->port_write_msg.discard_count++; pr_debug("RIO: Port Discarded Port-Write Msg(s) (%d)\n", pw->port_write_msg.discard_count); out_be32(&pw->pw_regs->pwsr, RIO_IPWSR_PWD); } pw_done: if (epwisr & RIO_EPWISR_PINT1) { tmp = in_be32(rio_regs_win + RIO_LTLEDCSR); pr_debug("RIO_LTLEDCSR = 0x%x\n", tmp); fsl_rio_port_error_handler(0); } if (epwisr & RIO_EPWISR_PINT2) { tmp = in_be32(rio_regs_win + RIO_LTLEDCSR); pr_debug("RIO_LTLEDCSR = 0x%x\n", tmp); fsl_rio_port_error_handler(1); } if (epwisr & RIO_EPWISR_MU) { tmp = in_be32(rio_regs_win + RIO_LTLEDCSR); pr_debug("RIO_LTLEDCSR = 0x%x\n", tmp); msg_unit_error_handler(); } return IRQ_HANDLED; } static void fsl_pw_dpc(struct work_struct *work) { struct fsl_rio_pw *pw = container_of(work, struct fsl_rio_pw, pw_work); union rio_pw_msg msg_buffer; int i; /* * Process port-write messages */ while (kfifo_out_spinlocked(&pw->pw_fifo, (unsigned char *)&msg_buffer, RIO_PW_MSG_SIZE, &pw->pw_fifo_lock)) { #ifdef DEBUG_PW { u32 i; pr_debug("%s : Port-Write Message:", __func__); for (i = 0; i < RIO_PW_MSG_SIZE/sizeof(u32); i++) { if ((i%4) == 0) pr_debug("\n0x%02x: 0x%08x", i*4, msg_buffer.raw[i]); else pr_debug(" 0x%08x", msg_buffer.raw[i]); } pr_debug("\n"); } #endif /* Pass the port-write message to RIO core for processing */ for (i = 0; i < MAX_PORT_NUM; i++) { if (pw->mport[i]) rio_inb_pwrite_handler(pw->mport[i], &msg_buffer); } } } /** * fsl_rio_pw_enable - enable/disable port-write interface init * @mport: Master port implementing the port write unit * @enable: 1=enable; 0=disable port-write message handling */ int fsl_rio_pw_enable(struct rio_mport *mport, int enable) { u32 rval; rval = in_be32(&pw->pw_regs->pwmr); if (enable) rval |= RIO_IPWMR_PWE; else rval &= ~RIO_IPWMR_PWE; out_be32(&pw->pw_regs->pwmr, rval); return 0; } /** * fsl_rio_port_write_init - MPC85xx port write interface init * @mport: Master port implementing the port write unit * * Initializes port write unit hardware and DMA buffer * ring. Called from fsl_rio_setup(). Returns %0 on success * or %-ENOMEM on failure. */ int fsl_rio_port_write_init(struct fsl_rio_pw *pw) { int rc = 0; /* Following configurations require a disabled port write controller */ out_be32(&pw->pw_regs->pwmr, in_be32(&pw->pw_regs->pwmr) & ~RIO_IPWMR_PWE); /* Initialize port write */ pw->port_write_msg.virt = dma_alloc_coherent(pw->dev, RIO_PW_MSG_SIZE, &pw->port_write_msg.phys, GFP_KERNEL); if (!pw->port_write_msg.virt) { pr_err("RIO: unable allocate port write queue\n"); return -ENOMEM; } pw->port_write_msg.err_count = 0; pw->port_write_msg.discard_count = 0; /* Point dequeue/enqueue pointers at first entry */ out_be32(&pw->pw_regs->epwqbar, 0); out_be32(&pw->pw_regs->pwqbar, (u32) pw->port_write_msg.phys); pr_debug("EIPWQBAR: 0x%08x IPWQBAR: 0x%08x\n", in_be32(&pw->pw_regs->epwqbar), in_be32(&pw->pw_regs->pwqbar)); /* Clear interrupt status IPWSR */ out_be32(&pw->pw_regs->pwsr, (RIO_IPWSR_TE | RIO_IPWSR_QFI | RIO_IPWSR_PWD)); /* Configure port write controller for snooping enable all reporting, clear queue full */ out_be32(&pw->pw_regs->pwmr, RIO_IPWMR_SEN | RIO_IPWMR_QFIE | RIO_IPWMR_EIE | RIO_IPWMR_CQ); /* Hook up port-write handler */ rc = request_irq(IRQ_RIO_PW(pw), fsl_rio_port_write_handler, IRQF_SHARED, "port-write", (void *)pw); if (rc < 0) { pr_err("MPC85xx RIO: unable to request inbound doorbell irq"); goto err_out; } /* Enable Error Interrupt */ out_be32((u32 *)(rio_regs_win + RIO_LTLEECSR), LTLEECSR_ENABLE_ALL); INIT_WORK(&pw->pw_work, fsl_pw_dpc); spin_lock_init(&pw->pw_fifo_lock); if (kfifo_alloc(&pw->pw_fifo, RIO_PW_MSG_SIZE * 32, GFP_KERNEL)) { pr_err("FIFO allocation failed\n"); rc = -ENOMEM; goto err_out_irq; } pr_debug("IPWMR: 0x%08x IPWSR: 0x%08x\n", in_be32(&pw->pw_regs->pwmr), in_be32(&pw->pw_regs->pwsr)); return rc; err_out_irq: free_irq(IRQ_RIO_PW(pw), (void *)pw); err_out: dma_free_coherent(pw->dev, RIO_PW_MSG_SIZE, pw->port_write_msg.virt, pw->port_write_msg.phys); return rc; } /** * fsl_rio_doorbell_send - Send a MPC85xx doorbell message * @mport: RapidIO master port info * @index: ID of RapidIO interface * @destid: Destination ID of target device * @data: 16-bit info field of RapidIO doorbell message * * Sends a MPC85xx doorbell message. Returns %0 on success or * %-EINVAL on failure. */ int fsl_rio_doorbell_send(struct rio_mport *mport, int index, u16 destid, u16 data) { unsigned long flags; pr_debug("fsl_doorbell_send: index %d destid %4.4x data %4.4x\n", index, destid, data); spin_lock_irqsave(&fsl_rio_doorbell_lock, flags); /* In the serial version silicons, such as MPC8548, MPC8641, * below operations is must be. */ out_be32(&dbell->dbell_regs->odmr, 0x00000000); out_be32(&dbell->dbell_regs->odretcr, 0x00000004); out_be32(&dbell->dbell_regs->oddpr, destid << 16); out_be32(&dbell->dbell_regs->oddatr, (index << 20) | data); out_be32(&dbell->dbell_regs->odmr, 0x00000001); spin_unlock_irqrestore(&fsl_rio_doorbell_lock, flags); return 0; } /** * fsl_add_outb_message - Add message to the MPC85xx outbound message queue * @mport: Master port with outbound message queue * @rdev: Target of outbound message * @mbox: Outbound mailbox * @buffer: Message to add to outbound queue * @len: Length of message * * Adds the @buffer message to the MPC85xx outbound message queue. Returns * %0 on success or %-EINVAL on failure. */ int fsl_add_outb_message(struct rio_mport *mport, struct rio_dev *rdev, int mbox, void *buffer, size_t len) { struct fsl_rmu *rmu = GET_RMM_HANDLE(mport); u32 omr; struct rio_tx_desc *desc = (struct rio_tx_desc *)rmu->msg_tx_ring.virt + rmu->msg_tx_ring.tx_slot; int ret = 0; pr_debug("RIO: fsl_add_outb_message(): destid %4.4x mbox %d buffer " \ "%p len %8.8zx\n", rdev->destid, mbox, buffer, len); if ((len < 8) || (len > RIO_MAX_MSG_SIZE)) { ret = -EINVAL; goto out; } /* Copy and clear rest of buffer */ memcpy(rmu->msg_tx_ring.virt_buffer[rmu->msg_tx_ring.tx_slot], buffer, len); if (len < (RIO_MAX_MSG_SIZE - 4)) memset(rmu->msg_tx_ring.virt_buffer[rmu->msg_tx_ring.tx_slot] + len, 0, RIO_MAX_MSG_SIZE - len); /* Set mbox field for message, and set destid */ desc->dport = (rdev->destid << 16) | (mbox & 0x3); /* Enable EOMI interrupt and priority */ desc->dattr = 0x28000000 | ((mport->index) << 20); /* Set transfer size aligned to next power of 2 (in double words) */ desc->dwcnt = is_power_of_2(len) ? len : 1 << get_bitmask_order(len); /* Set snooping and source buffer address */ desc->saddr = 0x00000004 | rmu->msg_tx_ring.phys_buffer[rmu->msg_tx_ring.tx_slot]; /* Increment enqueue pointer */ omr = in_be32(&rmu->msg_regs->omr); out_be32(&rmu->msg_regs->omr, omr | RIO_MSG_OMR_MUI); /* Go to next descriptor */ if (++rmu->msg_tx_ring.tx_slot == rmu->msg_tx_ring.size) rmu->msg_tx_ring.tx_slot = 0; out: return ret; } /** * fsl_open_outb_mbox - Initialize MPC85xx outbound mailbox * @mport: Master port implementing the outbound message unit * @dev_id: Device specific pointer to pass on event * @mbox: Mailbox to open * @entries: Number of entries in the outbound mailbox ring * * Initializes buffer ring, request the outbound message interrupt, * and enables the outbound message unit. Returns %0 on success and * %-EINVAL or %-ENOMEM on failure. */ int fsl_open_outb_mbox(struct rio_mport *mport, void *dev_id, int mbox, int entries) { int i, j, rc = 0; struct rio_priv *priv = mport->priv; struct fsl_rmu *rmu = GET_RMM_HANDLE(mport); if ((entries < RIO_MIN_TX_RING_SIZE) || (entries > RIO_MAX_TX_RING_SIZE) || (!is_power_of_2(entries))) { rc = -EINVAL; goto out; } /* Initialize shadow copy ring */ rmu->msg_tx_ring.dev_id = dev_id; rmu->msg_tx_ring.size = entries; for (i = 0; i < rmu->msg_tx_ring.size; i++) { rmu->msg_tx_ring.virt_buffer[i] = dma_alloc_coherent(priv->dev, RIO_MSG_BUFFER_SIZE, &rmu->msg_tx_ring.phys_buffer[i], GFP_KERNEL); if (!rmu->msg_tx_ring.virt_buffer[i]) { rc = -ENOMEM; for (j = 0; j < rmu->msg_tx_ring.size; j++) if (rmu->msg_tx_ring.virt_buffer[j]) dma_free_coherent(priv->dev, RIO_MSG_BUFFER_SIZE, rmu->msg_tx_ring. virt_buffer[j], rmu->msg_tx_ring. phys_buffer[j]); goto out; } } /* Initialize outbound message descriptor ring */ rmu->msg_tx_ring.virt = dma_alloc_coherent(priv->dev, rmu->msg_tx_ring.size * RIO_MSG_DESC_SIZE, &rmu->msg_tx_ring.phys, GFP_KERNEL); if (!rmu->msg_tx_ring.virt) { rc = -ENOMEM; goto out_dma; } rmu->msg_tx_ring.tx_slot = 0; /* Point dequeue/enqueue pointers at first entry in ring */ out_be32(&rmu->msg_regs->odqdpar, rmu->msg_tx_ring.phys); out_be32(&rmu->msg_regs->odqepar, rmu->msg_tx_ring.phys); /* Configure for snooping */ out_be32(&rmu->msg_regs->osar, 0x00000004); /* Clear interrupt status */ out_be32(&rmu->msg_regs->osr, 0x000000b3); /* Hook up outbound message handler */ rc = request_irq(IRQ_RIO_TX(mport), fsl_rio_tx_handler, 0, "msg_tx", (void *)mport); if (rc < 0) goto out_irq; /* * Configure outbound message unit * Snooping * Interrupts (all enabled, except QEIE) * Chaining mode * Disable */ out_be32(&rmu->msg_regs->omr, 0x00100220); /* Set number of entries */ out_be32(&rmu->msg_regs->omr, in_be32(&rmu->msg_regs->omr) | ((get_bitmask_order(entries) - 2) << 12)); /* Now enable the unit */ out_be32(&rmu->msg_regs->omr, in_be32(&rmu->msg_regs->omr) | 0x1); out: return rc; out_irq: dma_free_coherent(priv->dev, rmu->msg_tx_ring.size * RIO_MSG_DESC_SIZE, rmu->msg_tx_ring.virt, rmu->msg_tx_ring.phys); out_dma: for (i = 0; i < rmu->msg_tx_ring.size; i++) dma_free_coherent(priv->dev, RIO_MSG_BUFFER_SIZE, rmu->msg_tx_ring.virt_buffer[i], rmu->msg_tx_ring.phys_buffer[i]); return rc; } /** * fsl_close_outb_mbox - Shut down MPC85xx outbound mailbox * @mport: Master port implementing the outbound message unit * @mbox: Mailbox to close * * Disables the outbound message unit, free all buffers, and * frees the outbound message interrupt. */ void fsl_close_outb_mbox(struct rio_mport *mport, int mbox) { struct rio_priv *priv = mport->priv; struct fsl_rmu *rmu = GET_RMM_HANDLE(mport); /* Disable inbound message unit */ out_be32(&rmu->msg_regs->omr, 0); /* Free ring */ dma_free_coherent(priv->dev, rmu->msg_tx_ring.size * RIO_MSG_DESC_SIZE, rmu->msg_tx_ring.virt, rmu->msg_tx_ring.phys); /* Free interrupt */ free_irq(IRQ_RIO_TX(mport), (void *)mport); } /** * fsl_open_inb_mbox - Initialize MPC85xx inbound mailbox * @mport: Master port implementing the inbound message unit * @dev_id: Device specific pointer to pass on event * @mbox: Mailbox to open * @entries: Number of entries in the inbound mailbox ring * * Initializes buffer ring, request the inbound message interrupt, * and enables the inbound message unit. Returns %0 on success * and %-EINVAL or %-ENOMEM on failure. */ int fsl_open_inb_mbox(struct rio_mport *mport, void *dev_id, int mbox, int entries) { int i, rc = 0; struct rio_priv *priv = mport->priv; struct fsl_rmu *rmu = GET_RMM_HANDLE(mport); if ((entries < RIO_MIN_RX_RING_SIZE) || (entries > RIO_MAX_RX_RING_SIZE) || (!is_power_of_2(entries))) { rc = -EINVAL; goto out; } /* Initialize client buffer ring */ rmu->msg_rx_ring.dev_id = dev_id; rmu->msg_rx_ring.size = entries; rmu->msg_rx_ring.rx_slot = 0; for (i = 0; i < rmu->msg_rx_ring.size; i++) rmu->msg_rx_ring.virt_buffer[i] = NULL; /* Initialize inbound message ring */ rmu->msg_rx_ring.virt = dma_alloc_coherent(priv->dev, rmu->msg_rx_ring.size * RIO_MAX_MSG_SIZE, &rmu->msg_rx_ring.phys, GFP_KERNEL); if (!rmu->msg_rx_ring.virt) { rc = -ENOMEM; goto out; } /* Point dequeue/enqueue pointers at first entry in ring */ out_be32(&rmu->msg_regs->ifqdpar, (u32) rmu->msg_rx_ring.phys); out_be32(&rmu->msg_regs->ifqepar, (u32) rmu->msg_rx_ring.phys); /* Clear interrupt status */ out_be32(&rmu->msg_regs->isr, 0x00000091); /* Hook up inbound message handler */ rc = request_irq(IRQ_RIO_RX(mport), fsl_rio_rx_handler, 0, "msg_rx", (void *)mport); if (rc < 0) { dma_free_coherent(priv->dev, rmu->msg_rx_ring.size * RIO_MAX_MSG_SIZE, rmu->msg_rx_ring.virt, rmu->msg_rx_ring.phys); goto out; } /* * Configure inbound message unit: * Snooping * 4KB max message size * Unmask all interrupt sources * Disable */ out_be32(&rmu->msg_regs->imr, 0x001b0060); /* Set number of queue entries */ setbits32(&rmu->msg_regs->imr, (get_bitmask_order(entries) - 2) << 12); /* Now enable the unit */ setbits32(&rmu->msg_regs->imr, 0x1); out: return rc; } /** * fsl_close_inb_mbox - Shut down MPC85xx inbound mailbox * @mport: Master port implementing the inbound message unit * @mbox: Mailbox to close * * Disables the inbound message unit, free all buffers, and * frees the inbound message interrupt. */ void fsl_close_inb_mbox(struct rio_mport *mport, int mbox) { struct rio_priv *priv = mport->priv; struct fsl_rmu *rmu = GET_RMM_HANDLE(mport); /* Disable inbound message unit */ out_be32(&rmu->msg_regs->imr, 0); /* Free ring */ dma_free_coherent(priv->dev, rmu->msg_rx_ring.size * RIO_MAX_MSG_SIZE, rmu->msg_rx_ring.virt, rmu->msg_rx_ring.phys); /* Free interrupt */ free_irq(IRQ_RIO_RX(mport), (void *)mport); } /** * fsl_add_inb_buffer - Add buffer to the MPC85xx inbound message queue * @mport: Master port implementing the inbound message unit * @mbox: Inbound mailbox number * @buf: Buffer to add to inbound queue * * Adds the @buf buffer to the MPC85xx inbound message queue. Returns * %0 on success or %-EINVAL on failure. */ int fsl_add_inb_buffer(struct rio_mport *mport, int mbox, void *buf) { int rc = 0; struct fsl_rmu *rmu = GET_RMM_HANDLE(mport); pr_debug("RIO: fsl_add_inb_buffer(), msg_rx_ring.rx_slot %d\n", rmu->msg_rx_ring.rx_slot); if (rmu->msg_rx_ring.virt_buffer[rmu->msg_rx_ring.rx_slot]) { printk(KERN_ERR "RIO: error adding inbound buffer %d, buffer exists\n", rmu->msg_rx_ring.rx_slot); rc = -EINVAL; goto out; } rmu->msg_rx_ring.virt_buffer[rmu->msg_rx_ring.rx_slot] = buf; if (++rmu->msg_rx_ring.rx_slot == rmu->msg_rx_ring.size) rmu->msg_rx_ring.rx_slot = 0; out: return rc; } /** * fsl_get_inb_message - Fetch inbound message from the MPC85xx message unit * @mport: Master port implementing the inbound message unit * @mbox: Inbound mailbox number * * Gets the next available inbound message from the inbound message queue. * A pointer to the message is returned on success or NULL on failure. */ void *fsl_get_inb_message(struct rio_mport *mport, int mbox) { struct fsl_rmu *rmu = GET_RMM_HANDLE(mport); u32 phys_buf; void *virt_buf; void *buf = NULL; int buf_idx; phys_buf = in_be32(&rmu->msg_regs->ifqdpar); /* If no more messages, then bail out */ if (phys_buf == in_be32(&rmu->msg_regs->ifqepar)) goto out2; virt_buf = rmu->msg_rx_ring.virt + (phys_buf - rmu->msg_rx_ring.phys); buf_idx = (phys_buf - rmu->msg_rx_ring.phys) / RIO_MAX_MSG_SIZE; buf = rmu->msg_rx_ring.virt_buffer[buf_idx]; if (!buf) { printk(KERN_ERR "RIO: inbound message copy failed, no buffers\n"); goto out1; } /* Copy max message size, caller is expected to allocate that big */ memcpy(buf, virt_buf, RIO_MAX_MSG_SIZE); /* Clear the available buffer */ rmu->msg_rx_ring.virt_buffer[buf_idx] = NULL; out1: setbits32(&rmu->msg_regs->imr, RIO_MSG_IMR_MI); out2: return buf; } /** * fsl_rio_doorbell_init - MPC85xx doorbell interface init * @mport: Master port implementing the inbound doorbell unit * * Initializes doorbell unit hardware and inbound DMA buffer * ring. Called from fsl_rio_setup(). Returns %0 on success * or %-ENOMEM on failure. */ int fsl_rio_doorbell_init(struct fsl_rio_dbell *dbell) { int rc = 0; /* Initialize inbound doorbells */ dbell->dbell_ring.virt = dma_alloc_coherent(dbell->dev, 512 * DOORBELL_MESSAGE_SIZE, &dbell->dbell_ring.phys, GFP_KERNEL); if (!dbell->dbell_ring.virt) { printk(KERN_ERR "RIO: unable allocate inbound doorbell ring\n"); rc = -ENOMEM; goto out; } /* Point dequeue/enqueue pointers at first entry in ring */ out_be32(&dbell->dbell_regs->dqdpar, (u32) dbell->dbell_ring.phys); out_be32(&dbell->dbell_regs->dqepar, (u32) dbell->dbell_ring.phys); /* Clear interrupt status */ out_be32(&dbell->dbell_regs->dsr, 0x00000091); /* Hook up doorbell handler */ rc = request_irq(IRQ_RIO_BELL(dbell), fsl_rio_dbell_handler, 0, "dbell_rx", (void *)dbell); if (rc < 0) { dma_free_coherent(dbell->dev, 512 * DOORBELL_MESSAGE_SIZE, dbell->dbell_ring.virt, dbell->dbell_ring.phys); printk(KERN_ERR "MPC85xx RIO: unable to request inbound doorbell irq"); goto out; } /* Configure doorbells for snooping, 512 entries, and enable */ out_be32(&dbell->dbell_regs->dmr, 0x00108161); out: return rc; } int fsl_rio_setup_rmu(struct rio_mport *mport, struct device_node *node) { struct rio_priv *priv; struct fsl_rmu *rmu; u64 msg_start; if (!mport || !mport->priv) return -EINVAL; priv = mport->priv; if (!node) { dev_warn(priv->dev, "Can't get %pOF property 'fsl,rmu'\n", priv->dev->of_node); return -EINVAL; } rmu = kzalloc(sizeof(struct fsl_rmu), GFP_KERNEL); if (!rmu) return -ENOMEM; if (of_property_read_reg(node, 0, &msg_start, NULL)) { pr_err("%pOF: unable to find 'reg' property of message-unit\n", node); kfree(rmu); return -ENOMEM; } rmu->msg_regs = (struct rio_msg_regs *) (rmu_regs_win + (u32)msg_start); rmu->txirq = irq_of_parse_and_map(node, 0); rmu->rxirq = irq_of_parse_and_map(node, 1); printk(KERN_INFO "%pOF: txirq: %d, rxirq %d\n", node, rmu->txirq, rmu->rxirq); priv->rmm_handle = rmu; rio_init_dbell_res(&mport->riores[RIO_DOORBELL_RESOURCE], 0, 0xffff); rio_init_mbox_res(&mport->riores[RIO_INB_MBOX_RESOURCE], 0, 0); rio_init_mbox_res(&mport->riores[RIO_OUTB_MBOX_RESOURCE], 0, 0); return 0; }