/* * This file is provided under a CDDLv1 license. When using or * redistributing this file, you may do so under this license. * In redistributing this file this license must be included * and no other modification of this header file is permitted. * * CDDL LICENSE SUMMARY * * Copyright(c) 1999 - 2008 Intel Corporation. All rights reserved. * * The contents of this file are subject to the terms of Version * 1.0 of the Common Development and Distribution License (the "License"). * * You should have received a copy of the License with this software. * You can obtain a copy of the License at * http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms of the CDDLv1. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * ********************************************************************** * Module Name: * * e1000g_alloc.c * * * * Abstract: * * This file contains some routines that take care of * * memory allocation for descriptors and buffers. * * * * ********************************************************************** */ #include "e1000g_sw.h" #include "e1000g_debug.h" #define TX_SW_PKT_AREA_SZ \ (sizeof (tx_sw_packet_t) * Adapter->tx_freelist_num) static int e1000g_alloc_tx_descriptors(e1000g_tx_ring_t *); static int e1000g_alloc_rx_descriptors(e1000g_rx_ring_t *); static void e1000g_free_tx_descriptors(e1000g_tx_ring_t *); static void e1000g_free_rx_descriptors(e1000g_rx_ring_t *); static int e1000g_alloc_tx_packets(e1000g_tx_ring_t *); static int e1000g_alloc_rx_packets(e1000g_rx_ring_t *); static void e1000g_free_tx_packets(e1000g_tx_ring_t *); static void e1000g_free_rx_packets(e1000g_rx_ring_t *); static int e1000g_alloc_dma_buffer(struct e1000g *, dma_buffer_t *, size_t, ddi_dma_attr_t *p_dma_attr); static void e1000g_free_dma_buffer(dma_buffer_t *); #ifdef __sparc static int e1000g_alloc_dvma_buffer(struct e1000g *, dma_buffer_t *, size_t); static void e1000g_free_dvma_buffer(dma_buffer_t *); #endif static int e1000g_alloc_descriptors(struct e1000g *Adapter); static void e1000g_free_descriptors(struct e1000g *Adapter); static int e1000g_alloc_packets(struct e1000g *Adapter); static void e1000g_free_packets(struct e1000g *Adapter); static p_rx_sw_packet_t e1000g_alloc_rx_sw_packet(e1000g_rx_ring_t *, ddi_dma_attr_t *p_dma_attr); /* DMA access attributes for descriptors */ static ddi_device_acc_attr_t e1000g_desc_acc_attr = { DDI_DEVICE_ATTR_V0, DDI_STRUCTURE_LE_ACC, DDI_STRICTORDER_ACC, DDI_FLAGERR_ACC }; /* DMA access attributes for DMA buffers */ #ifdef __sparc static ddi_device_acc_attr_t e1000g_buf_acc_attr = { DDI_DEVICE_ATTR_V0, DDI_STRUCTURE_BE_ACC, DDI_STRICTORDER_ACC, }; #else static ddi_device_acc_attr_t e1000g_buf_acc_attr = { DDI_DEVICE_ATTR_V0, DDI_STRUCTURE_LE_ACC, DDI_STRICTORDER_ACC, }; #endif /* DMA attributes for tx mblk buffers */ static ddi_dma_attr_t e1000g_tx_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffffffffffULL, /* highest usable address */ 0x7fffffff, /* maximum DMAable byte count */ 1, /* alignment in bytes */ 0x7ff, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffffffffffULL, /* maximum segment length */ 18, /* maximum number of segments */ 1, /* granularity */ DDI_DMA_FLAGERR, /* dma_attr_flags */ }; /* DMA attributes for pre-allocated rx/tx buffers */ static ddi_dma_attr_t e1000g_buf_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffffffffffULL, /* highest usable address */ 0x7fffffff, /* maximum DMAable byte count */ 1, /* alignment in bytes */ 0x7ff, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffffffffffULL, /* maximum segment length */ 1, /* maximum number of segments */ 1, /* granularity */ DDI_DMA_FLAGERR, /* dma_attr_flags */ }; /* DMA attributes for rx/tx descriptors */ static ddi_dma_attr_t e1000g_desc_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffffffffffULL, /* highest usable address */ 0x7fffffff, /* maximum DMAable byte count */ E1000_MDALIGN, /* alignment in bytes 4K! */ 0x7ff, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffffffffffULL, /* maximum segment length */ 1, /* maximum number of segments */ 1, /* granularity */ DDI_DMA_FLAGERR, /* dma_attr_flags */ }; #ifdef __sparc static ddi_dma_lim_t e1000g_dma_limits = { (uint_t)0, /* dlim_addr_lo */ (uint_t)0xffffffff, /* dlim_addr_hi */ (uint_t)0xffffffff, /* dlim_cntr_max */ (uint_t)0xfc00fc, /* dlim_burstsizes for 32 and 64 bit xfers */ 0x1, /* dlim_minxfer */ 1024 /* dlim_speed */ }; #endif #ifdef __sparc static dma_type_t e1000g_dma_type = USE_DVMA; #else static dma_type_t e1000g_dma_type = USE_DMA; #endif extern krwlock_t e1000g_dma_type_lock; int e1000g_alloc_dma_resources(struct e1000g *Adapter) { int result; result = DDI_FAILURE; while ((result != DDI_SUCCESS) && (Adapter->tx_desc_num >= MIN_NUM_TX_DESCRIPTOR) && (Adapter->rx_desc_num >= MIN_NUM_RX_DESCRIPTOR) && (Adapter->tx_freelist_num >= MIN_NUM_TX_FREELIST) && (Adapter->rx_freelist_num >= MIN_NUM_RX_FREELIST)) { result = e1000g_alloc_descriptors(Adapter); if (result == DDI_SUCCESS) { result = e1000g_alloc_packets(Adapter); if (result != DDI_SUCCESS) e1000g_free_descriptors(Adapter); } /* * If the allocation fails due to resource shortage, * we'll reduce the numbers of descriptors/buffers by * half, and try the allocation again. */ if (result != DDI_SUCCESS) { /* * We must ensure the number of descriptors * is always a multiple of 8. */ Adapter->tx_desc_num = (Adapter->tx_desc_num >> 4) << 3; Adapter->rx_desc_num = (Adapter->rx_desc_num >> 4) << 3; Adapter->tx_freelist_num >>= 1; Adapter->rx_freelist_num >>= 1; } } return (result); } /* * e1000g_alloc_descriptors - allocate DMA buffers for descriptors * * This routine allocates neccesary DMA buffers for * Transmit Descriptor Area * Receive Descrpitor Area */ static int e1000g_alloc_descriptors(struct e1000g *Adapter) { int result; e1000g_tx_ring_t *tx_ring; e1000g_rx_ring_t *rx_ring; tx_ring = Adapter->tx_ring; result = e1000g_alloc_tx_descriptors(tx_ring); if (result != DDI_SUCCESS) return (DDI_FAILURE); rx_ring = Adapter->rx_ring; result = e1000g_alloc_rx_descriptors(rx_ring); if (result != DDI_SUCCESS) { e1000g_free_tx_descriptors(tx_ring); return (DDI_FAILURE); } return (DDI_SUCCESS); } static void e1000g_free_descriptors(struct e1000g *Adapter) { e1000g_tx_ring_t *tx_ring; e1000g_rx_ring_t *rx_ring; tx_ring = Adapter->tx_ring; rx_ring = Adapter->rx_ring; e1000g_free_tx_descriptors(tx_ring); e1000g_free_rx_descriptors(rx_ring); } static int e1000g_alloc_tx_descriptors(e1000g_tx_ring_t *tx_ring) { int mystat; boolean_t alloc_flag; size_t size; size_t len; uintptr_t templong; uint_t cookie_count; dev_info_t *devinfo; ddi_dma_cookie_t cookie; struct e1000g *Adapter; ddi_dma_attr_t dma_attr; Adapter = tx_ring->adapter; devinfo = Adapter->dip; alloc_flag = B_FALSE; dma_attr = e1000g_desc_dma_attr; /* * Solaris 7 has a problem with allocating physically contiguous memory * that is aligned on a 4K boundary. The transmit and rx descriptors * need to aligned on a 4kbyte boundary. We first try to allocate the * memory with DMA attributes set to 4K alignment and also no scatter/ * gather mechanism specified. In most cases, this does not allocate * memory aligned at a 4Kbyte boundary. We then try asking for memory * aligned on 4K boundary with scatter/gather set to 2. This works when * the amount of memory is less than 4k i.e a page size. If neither of * these options work or if the number of descriptors is greater than * 4K, ie more than 256 descriptors, we allocate 4k extra memory and * and then align the memory at a 4k boundary. */ size = sizeof (struct e1000_tx_desc) * Adapter->tx_desc_num; /* * Memory allocation for the transmit buffer descriptors. */ dma_attr.dma_attr_sgllen = 1; /* * Allocate a new DMA handle for the transmit descriptor * memory area. */ mystat = ddi_dma_alloc_handle(devinfo, &dma_attr, DDI_DMA_DONTWAIT, 0, &tx_ring->tbd_dma_handle); if (mystat != DDI_SUCCESS) { E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not allocate tbd dma handle: %d", mystat); tx_ring->tbd_dma_handle = NULL; return (DDI_FAILURE); } /* * Allocate memory to DMA data to and from the transmit * descriptors. */ mystat = ddi_dma_mem_alloc(tx_ring->tbd_dma_handle, size, &e1000g_desc_acc_attr, DDI_DMA_CONSISTENT, DDI_DMA_DONTWAIT, 0, (caddr_t *)&tx_ring->tbd_area, &len, &tx_ring->tbd_acc_handle); if ((mystat != DDI_SUCCESS) || ((uintptr_t)tx_ring->tbd_area & (E1000_MDALIGN - 1))) { if (mystat == DDI_SUCCESS) { ddi_dma_mem_free(&tx_ring->tbd_acc_handle); tx_ring->tbd_acc_handle = NULL; tx_ring->tbd_area = NULL; } if (tx_ring->tbd_dma_handle != NULL) { ddi_dma_free_handle(&tx_ring->tbd_dma_handle); tx_ring->tbd_dma_handle = NULL; } alloc_flag = B_FALSE; } else alloc_flag = B_TRUE; /* * Initialize the entire transmit buffer descriptor area to zero */ if (alloc_flag) bzero(tx_ring->tbd_area, len); /* * If the previous DMA attributes setting could not give us contiguous * memory or the number of descriptors is greater than the page size, * we allocate 4K extra memory and then align it at a 4k boundary. */ if (!alloc_flag) { size = size + ROUNDOFF; /* * DMA attributes set to no scatter/gather and 16 bit alignment */ dma_attr.dma_attr_align = 1; dma_attr.dma_attr_sgllen = 1; /* * Allocate a new DMA handle for the transmit descriptor memory * area. */ mystat = ddi_dma_alloc_handle(devinfo, &dma_attr, DDI_DMA_DONTWAIT, 0, &tx_ring->tbd_dma_handle); if (mystat != DDI_SUCCESS) { E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not re-allocate tbd dma handle: %d", mystat); tx_ring->tbd_dma_handle = NULL; return (DDI_FAILURE); } /* * Allocate memory to DMA data to and from the transmit * descriptors. */ mystat = ddi_dma_mem_alloc(tx_ring->tbd_dma_handle, size, &e1000g_desc_acc_attr, DDI_DMA_CONSISTENT, DDI_DMA_DONTWAIT, 0, (caddr_t *)&tx_ring->tbd_area, &len, &tx_ring->tbd_acc_handle); if (mystat != DDI_SUCCESS) { E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not allocate tbd dma memory: %d", mystat); tx_ring->tbd_acc_handle = NULL; tx_ring->tbd_area = NULL; if (tx_ring->tbd_dma_handle != NULL) { ddi_dma_free_handle(&tx_ring->tbd_dma_handle); tx_ring->tbd_dma_handle = NULL; } return (DDI_FAILURE); } else alloc_flag = B_TRUE; /* * Initialize the entire transmit buffer descriptor area to zero */ bzero(tx_ring->tbd_area, len); /* * Memory has been allocated with the ddi_dma_mem_alloc call, * but has not been aligned. We now align it on a 4k boundary. */ templong = P2NPHASE((uintptr_t)tx_ring->tbd_area, ROUNDOFF); len = size - templong; templong += (uintptr_t)tx_ring->tbd_area; tx_ring->tbd_area = (struct e1000_tx_desc *)templong; } /* alignment workaround */ /* * Transmit buffer descriptor memory allocation succeeded */ ASSERT(alloc_flag); /* * Allocates DMA resources for the memory that was allocated by * the ddi_dma_mem_alloc call. The DMA resources then get bound to the * the memory address */ mystat = ddi_dma_addr_bind_handle(tx_ring->tbd_dma_handle, (struct as *)NULL, (caddr_t)tx_ring->tbd_area, len, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, DDI_DMA_DONTWAIT, 0, &cookie, &cookie_count); if (mystat != DDI_SUCCESS) { E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not bind tbd dma resource: %d", mystat); if (tx_ring->tbd_acc_handle != NULL) { ddi_dma_mem_free(&tx_ring->tbd_acc_handle); tx_ring->tbd_acc_handle = NULL; tx_ring->tbd_area = NULL; } if (tx_ring->tbd_dma_handle != NULL) { ddi_dma_free_handle(&tx_ring->tbd_dma_handle); tx_ring->tbd_dma_handle = NULL; } return (DDI_FAILURE); } ASSERT(cookie_count == 1); /* 1 cookie */ if (cookie_count != 1) { E1000G_DEBUGLOG_2(Adapter, E1000G_WARN_LEVEL, "Could not bind tbd dma resource in a single frag. " "Count - %d Len - %d", cookie_count, len); e1000g_free_tx_descriptors(tx_ring); return (DDI_FAILURE); } tx_ring->tbd_dma_addr = cookie.dmac_laddress; tx_ring->tbd_first = tx_ring->tbd_area; tx_ring->tbd_last = tx_ring->tbd_first + (Adapter->tx_desc_num - 1); return (DDI_SUCCESS); } static int e1000g_alloc_rx_descriptors(e1000g_rx_ring_t *rx_ring) { int mystat; boolean_t alloc_flag; size_t size; size_t len; uintptr_t templong; uint_t cookie_count; dev_info_t *devinfo; ddi_dma_cookie_t cookie; struct e1000g *Adapter; ddi_dma_attr_t dma_attr; Adapter = rx_ring->adapter; devinfo = Adapter->dip; alloc_flag = B_FALSE; dma_attr = e1000g_desc_dma_attr; /* * Memory allocation for the receive buffer descriptors. */ size = (sizeof (struct e1000_rx_desc)) * Adapter->rx_desc_num; /* * Asking for aligned memory with DMA attributes set for 4k alignment */ dma_attr.dma_attr_sgllen = 1; dma_attr.dma_attr_align = E1000_MDALIGN; /* * Allocate a new DMA handle for the receive descriptors */ mystat = ddi_dma_alloc_handle(devinfo, &dma_attr, DDI_DMA_DONTWAIT, 0, &rx_ring->rbd_dma_handle); if (mystat != DDI_SUCCESS) { E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not allocate rbd dma handle: %d", mystat); rx_ring->rbd_dma_handle = NULL; return (DDI_FAILURE); } /* * Allocate memory to DMA data to and from the receive * descriptors. */ mystat = ddi_dma_mem_alloc(rx_ring->rbd_dma_handle, size, &e1000g_desc_acc_attr, DDI_DMA_CONSISTENT, DDI_DMA_DONTWAIT, 0, (caddr_t *)&rx_ring->rbd_area, &len, &rx_ring->rbd_acc_handle); /* * Check if memory allocation succeeded and also if the * allocated memory is aligned correctly. */ if ((mystat != DDI_SUCCESS) || ((uintptr_t)rx_ring->rbd_area & (E1000_MDALIGN - 1))) { if (mystat == DDI_SUCCESS) { ddi_dma_mem_free(&rx_ring->rbd_acc_handle); rx_ring->rbd_acc_handle = NULL; rx_ring->rbd_area = NULL; } if (rx_ring->rbd_dma_handle != NULL) { ddi_dma_free_handle(&rx_ring->rbd_dma_handle); rx_ring->rbd_dma_handle = NULL; } alloc_flag = B_FALSE; } else alloc_flag = B_TRUE; /* * Initialize the allocated receive descriptor memory to zero. */ if (alloc_flag) bzero((caddr_t)rx_ring->rbd_area, len); /* * If memory allocation did not succeed, do the alignment ourselves */ if (!alloc_flag) { dma_attr.dma_attr_align = 1; dma_attr.dma_attr_sgllen = 1; size = size + ROUNDOFF; /* * Allocate a new DMA handle for the receive descriptor. */ mystat = ddi_dma_alloc_handle(devinfo, &dma_attr, DDI_DMA_DONTWAIT, 0, &rx_ring->rbd_dma_handle); if (mystat != DDI_SUCCESS) { E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not re-allocate rbd dma handle: %d", mystat); rx_ring->rbd_dma_handle = NULL; return (DDI_FAILURE); } /* * Allocate memory to DMA data to and from the receive * descriptors. */ mystat = ddi_dma_mem_alloc(rx_ring->rbd_dma_handle, size, &e1000g_desc_acc_attr, DDI_DMA_CONSISTENT, DDI_DMA_DONTWAIT, 0, (caddr_t *)&rx_ring->rbd_area, &len, &rx_ring->rbd_acc_handle); if (mystat != DDI_SUCCESS) { E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not allocate rbd dma memory: %d", mystat); rx_ring->rbd_acc_handle = NULL; rx_ring->rbd_area = NULL; if (rx_ring->rbd_dma_handle != NULL) { ddi_dma_free_handle(&rx_ring->rbd_dma_handle); rx_ring->rbd_dma_handle = NULL; } return (DDI_FAILURE); } else alloc_flag = B_TRUE; /* * Initialize the allocated receive descriptor memory to zero. */ bzero((caddr_t)rx_ring->rbd_area, len); templong = P2NPHASE((uintptr_t)rx_ring->rbd_area, ROUNDOFF); len = size - templong; templong += (uintptr_t)rx_ring->rbd_area; rx_ring->rbd_area = (struct e1000_rx_desc *)templong; } /* alignment workaround */ /* * The memory allocation of the receive descriptors succeeded */ ASSERT(alloc_flag); /* * Allocates DMA resources for the memory that was allocated by * the ddi_dma_mem_alloc call. */ mystat = ddi_dma_addr_bind_handle(rx_ring->rbd_dma_handle, (struct as *)NULL, (caddr_t)rx_ring->rbd_area, len, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, DDI_DMA_DONTWAIT, 0, &cookie, &cookie_count); if (mystat != DDI_SUCCESS) { E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not bind rbd dma resource: %d", mystat); if (rx_ring->rbd_acc_handle != NULL) { ddi_dma_mem_free(&rx_ring->rbd_acc_handle); rx_ring->rbd_acc_handle = NULL; rx_ring->rbd_area = NULL; } if (rx_ring->rbd_dma_handle != NULL) { ddi_dma_free_handle(&rx_ring->rbd_dma_handle); rx_ring->rbd_dma_handle = NULL; } return (DDI_FAILURE); } ASSERT(cookie_count == 1); if (cookie_count != 1) { E1000G_DEBUGLOG_2(Adapter, E1000G_WARN_LEVEL, "Could not bind rbd dma resource in a single frag. " "Count - %d Len - %d", cookie_count, len); e1000g_free_rx_descriptors(rx_ring); return (DDI_FAILURE); } rx_ring->rbd_dma_addr = cookie.dmac_laddress; rx_ring->rbd_first = rx_ring->rbd_area; rx_ring->rbd_last = rx_ring->rbd_first + (Adapter->rx_desc_num - 1); return (DDI_SUCCESS); } static void e1000g_free_rx_descriptors(e1000g_rx_ring_t *rx_ring) { if (rx_ring->rbd_dma_handle != NULL) { ddi_dma_unbind_handle(rx_ring->rbd_dma_handle); } if (rx_ring->rbd_acc_handle != NULL) { ddi_dma_mem_free(&rx_ring->rbd_acc_handle); rx_ring->rbd_acc_handle = NULL; rx_ring->rbd_area = NULL; } if (rx_ring->rbd_dma_handle != NULL) { ddi_dma_free_handle(&rx_ring->rbd_dma_handle); rx_ring->rbd_dma_handle = NULL; } rx_ring->rbd_dma_addr = NULL; rx_ring->rbd_first = NULL; rx_ring->rbd_last = NULL; } static void e1000g_free_tx_descriptors(e1000g_tx_ring_t *tx_ring) { if (tx_ring->tbd_dma_handle != NULL) { ddi_dma_unbind_handle(tx_ring->tbd_dma_handle); } if (tx_ring->tbd_acc_handle != NULL) { ddi_dma_mem_free(&tx_ring->tbd_acc_handle); tx_ring->tbd_acc_handle = NULL; tx_ring->tbd_area = NULL; } if (tx_ring->tbd_dma_handle != NULL) { ddi_dma_free_handle(&tx_ring->tbd_dma_handle); tx_ring->tbd_dma_handle = NULL; } tx_ring->tbd_dma_addr = NULL; tx_ring->tbd_first = NULL; tx_ring->tbd_last = NULL; } /* * e1000g_alloc_packets - allocate DMA buffers for rx/tx * * This routine allocates neccesary buffers for * Transmit sw packet structure * DMA handle for Transmit * DMA buffer for Transmit * Receive sw packet structure * DMA buffer for Receive */ static int e1000g_alloc_packets(struct e1000g *Adapter) { int result; e1000g_tx_ring_t *tx_ring; e1000g_rx_ring_t *rx_ring; tx_ring = Adapter->tx_ring; rx_ring = Adapter->rx_ring; again: rw_enter(&e1000g_dma_type_lock, RW_READER); result = e1000g_alloc_tx_packets(tx_ring); if (result != DDI_SUCCESS) { if (e1000g_dma_type == USE_DVMA) { rw_exit(&e1000g_dma_type_lock); rw_enter(&e1000g_dma_type_lock, RW_WRITER); e1000g_dma_type = USE_DMA; rw_exit(&e1000g_dma_type_lock); E1000G_DEBUGLOG_0(Adapter, E1000G_INFO_LEVEL, "No enough dvma resource for Tx packets, " "trying to allocate dma buffers...\n"); goto again; } rw_exit(&e1000g_dma_type_lock); E1000G_DEBUGLOG_0(Adapter, E1000G_WARN_LEVEL, "Failed to allocate dma buffers for Tx packets\n"); return (DDI_FAILURE); } result = e1000g_alloc_rx_packets(rx_ring); if (result != DDI_SUCCESS) { e1000g_free_tx_packets(tx_ring); if (e1000g_dma_type == USE_DVMA) { rw_exit(&e1000g_dma_type_lock); rw_enter(&e1000g_dma_type_lock, RW_WRITER); e1000g_dma_type = USE_DMA; rw_exit(&e1000g_dma_type_lock); E1000G_DEBUGLOG_0(Adapter, E1000G_INFO_LEVEL, "No enough dvma resource for Rx packets, " "trying to allocate dma buffers...\n"); goto again; } rw_exit(&e1000g_dma_type_lock); E1000G_DEBUGLOG_0(Adapter, E1000G_WARN_LEVEL, "Failed to allocate dma buffers for Rx packets\n"); return (DDI_FAILURE); } rw_exit(&e1000g_dma_type_lock); return (DDI_SUCCESS); } static void e1000g_free_packets(struct e1000g *Adapter) { e1000g_tx_ring_t *tx_ring; e1000g_rx_ring_t *rx_ring; tx_ring = Adapter->tx_ring; rx_ring = Adapter->rx_ring; e1000g_free_tx_packets(tx_ring); e1000g_free_rx_packets(rx_ring); } #ifdef __sparc static int e1000g_alloc_dvma_buffer(struct e1000g *Adapter, dma_buffer_t *buf, size_t size) { int mystat; dev_info_t *devinfo; ddi_dma_cookie_t cookie; if (e1000g_force_detach) devinfo = Adapter->priv_dip; else devinfo = Adapter->dip; mystat = dvma_reserve(devinfo, &e1000g_dma_limits, Adapter->dvma_page_num, &buf->dma_handle); if (mystat != DDI_SUCCESS) { buf->dma_handle = NULL; E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not allocate dvma buffer handle: %d\n", mystat); return (DDI_FAILURE); } buf->address = kmem_alloc(size, KM_NOSLEEP); if (buf->address == NULL) { if (buf->dma_handle != NULL) { dvma_release(buf->dma_handle); buf->dma_handle = NULL; } E1000G_DEBUGLOG_0(Adapter, E1000G_WARN_LEVEL, "Could not allocate dvma buffer memory\n"); return (DDI_FAILURE); } dvma_kaddr_load(buf->dma_handle, buf->address, size, 0, &cookie); buf->dma_address = cookie.dmac_laddress; buf->size = size; buf->len = 0; return (DDI_SUCCESS); } static void e1000g_free_dvma_buffer(dma_buffer_t *buf) { if (buf->dma_handle != NULL) { dvma_unload(buf->dma_handle, 0, -1); } else { return; } buf->dma_address = NULL; if (buf->address != NULL) { kmem_free(buf->address, buf->size); buf->address = NULL; } if (buf->dma_handle != NULL) { dvma_release(buf->dma_handle); buf->dma_handle = NULL; } buf->size = 0; buf->len = 0; } #endif static int e1000g_alloc_dma_buffer(struct e1000g *Adapter, dma_buffer_t *buf, size_t size, ddi_dma_attr_t *p_dma_attr) { int mystat; dev_info_t *devinfo; ddi_dma_cookie_t cookie; size_t len; uint_t count; if (e1000g_force_detach) devinfo = Adapter->priv_dip; else devinfo = Adapter->dip; mystat = ddi_dma_alloc_handle(devinfo, p_dma_attr, DDI_DMA_DONTWAIT, 0, &buf->dma_handle); if (mystat != DDI_SUCCESS) { buf->dma_handle = NULL; E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not allocate dma buffer handle: %d\n", mystat); return (DDI_FAILURE); } mystat = ddi_dma_mem_alloc(buf->dma_handle, size, &e1000g_buf_acc_attr, DDI_DMA_STREAMING, DDI_DMA_DONTWAIT, 0, &buf->address, &len, &buf->acc_handle); if (mystat != DDI_SUCCESS) { buf->acc_handle = NULL; buf->address = NULL; if (buf->dma_handle != NULL) { ddi_dma_free_handle(&buf->dma_handle); buf->dma_handle = NULL; } E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not allocate dma buffer memory: %d\n", mystat); return (DDI_FAILURE); } mystat = ddi_dma_addr_bind_handle(buf->dma_handle, (struct as *)NULL, buf->address, len, DDI_DMA_READ | DDI_DMA_STREAMING, DDI_DMA_DONTWAIT, 0, &cookie, &count); if (mystat != DDI_SUCCESS) { if (buf->acc_handle != NULL) { ddi_dma_mem_free(&buf->acc_handle); buf->acc_handle = NULL; buf->address = NULL; } if (buf->dma_handle != NULL) { ddi_dma_free_handle(&buf->dma_handle); buf->dma_handle = NULL; } E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not bind buffer dma handle: %d\n", mystat); return (DDI_FAILURE); } ASSERT(count == 1); if (count != 1) { if (buf->dma_handle != NULL) { ddi_dma_unbind_handle(buf->dma_handle); } if (buf->acc_handle != NULL) { ddi_dma_mem_free(&buf->acc_handle); buf->acc_handle = NULL; buf->address = NULL; } if (buf->dma_handle != NULL) { ddi_dma_free_handle(&buf->dma_handle); buf->dma_handle = NULL; } E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not bind buffer as a single frag. " "Count = %d\n", count); return (DDI_FAILURE); } buf->dma_address = cookie.dmac_laddress; buf->size = len; buf->len = 0; return (DDI_SUCCESS); } static void e1000g_free_dma_buffer(dma_buffer_t *buf) { if (buf->dma_handle != NULL) { ddi_dma_unbind_handle(buf->dma_handle); } else { return; } buf->dma_address = NULL; if (buf->acc_handle != NULL) { ddi_dma_mem_free(&buf->acc_handle); buf->acc_handle = NULL; buf->address = NULL; } if (buf->dma_handle != NULL) { ddi_dma_free_handle(&buf->dma_handle); buf->dma_handle = NULL; } buf->size = 0; buf->len = 0; } static int e1000g_alloc_tx_packets(e1000g_tx_ring_t *tx_ring) { int j; p_tx_sw_packet_t packet; int mystat; dma_buffer_t *tx_buf; struct e1000g *Adapter; dev_info_t *devinfo; ddi_dma_attr_t dma_attr; Adapter = tx_ring->adapter; devinfo = Adapter->dip; dma_attr = e1000g_buf_dma_attr; /* * Memory allocation for the Transmit software structure, the transmit * software packet. This structure stores all the relevant information * for transmitting a single packet. */ tx_ring->packet_area = kmem_zalloc(TX_SW_PKT_AREA_SZ, KM_NOSLEEP); if (tx_ring->packet_area == NULL) return (DDI_FAILURE); for (j = 0, packet = tx_ring->packet_area; j < Adapter->tx_freelist_num; j++, packet++) { ASSERT(packet != NULL); /* * Pre-allocate dma handles for transmit. These dma handles * will be dynamically bound to the data buffers passed down * from the upper layers at the time of transmitting. The * dynamic binding only applies for the packets that are larger * than the tx_bcopy_thresh. */ switch (e1000g_dma_type) { #ifdef __sparc case USE_DVMA: mystat = dvma_reserve(devinfo, &e1000g_dma_limits, Adapter->dvma_page_num, &packet->tx_dma_handle); break; #endif case USE_DMA: mystat = ddi_dma_alloc_handle(devinfo, &e1000g_tx_dma_attr, DDI_DMA_DONTWAIT, 0, &packet->tx_dma_handle); break; default: ASSERT(B_FALSE); break; } if (mystat != DDI_SUCCESS) { packet->tx_dma_handle = NULL; E1000G_DEBUGLOG_1(Adapter, E1000G_WARN_LEVEL, "Could not allocate tx dma handle: %d\n", mystat); goto tx_pkt_fail; } /* * Pre-allocate transmit buffers for small packets that the * size is less than tx_bcopy_thresh. The data of those small * packets will be bcopy() to the transmit buffers instead of * using dynamical DMA binding. For small packets, bcopy will * bring better performance than DMA binding. */ tx_buf = packet->tx_buf; switch (e1000g_dma_type) { #ifdef __sparc case USE_DVMA: mystat = e1000g_alloc_dvma_buffer(Adapter, tx_buf, Adapter->tx_buffer_size); break; #endif case USE_DMA: mystat = e1000g_alloc_dma_buffer(Adapter, tx_buf, Adapter->tx_buffer_size, &dma_attr); break; default: ASSERT(B_FALSE); break; } if (mystat != DDI_SUCCESS) { ASSERT(packet->tx_dma_handle != NULL); switch (e1000g_dma_type) { #ifdef __sparc case USE_DVMA: dvma_release(packet->tx_dma_handle); break; #endif case USE_DMA: ddi_dma_free_handle(&packet->tx_dma_handle); break; default: ASSERT(B_FALSE); break; } packet->tx_dma_handle = NULL; E1000G_DEBUGLOG_0(Adapter, E1000G_WARN_LEVEL, "Allocate Tx buffer fail\n"); goto tx_pkt_fail; } packet->dma_type = e1000g_dma_type; } /* for */ return (DDI_SUCCESS); tx_pkt_fail: e1000g_free_tx_packets(tx_ring); return (DDI_FAILURE); } static int e1000g_alloc_rx_packets(e1000g_rx_ring_t *rx_ring) { int i; p_rx_sw_packet_t packet; struct e1000g *Adapter; uint32_t packet_num; ddi_dma_attr_t dma_attr; Adapter = rx_ring->adapter; dma_attr = e1000g_buf_dma_attr; dma_attr.dma_attr_align = Adapter->rx_buf_align; /* * Allocate memory for the rx_sw_packet structures. Each one of these * structures will contain a virtual and physical address to an actual * receive buffer in host memory. Since we use one rx_sw_packet per * received packet, the maximum number of rx_sw_packet that we'll * need is equal to the number of receive descriptors that we've * allocated. */ packet_num = Adapter->rx_desc_num + Adapter->rx_freelist_num; rx_ring->packet_area = NULL; for (i = 0; i < packet_num; i++) { packet = e1000g_alloc_rx_sw_packet(rx_ring, &dma_attr); if (packet == NULL) goto rx_pkt_fail; packet->next = rx_ring->packet_area; rx_ring->packet_area = packet; } return (DDI_SUCCESS); rx_pkt_fail: e1000g_free_rx_packets(rx_ring); return (DDI_FAILURE); } static p_rx_sw_packet_t e1000g_alloc_rx_sw_packet(e1000g_rx_ring_t *rx_ring, ddi_dma_attr_t *p_dma_attr) { int mystat; p_rx_sw_packet_t packet; dma_buffer_t *rx_buf; struct e1000g *Adapter; Adapter = rx_ring->adapter; packet = kmem_zalloc(sizeof (rx_sw_packet_t), KM_NOSLEEP); if (packet == NULL) { E1000G_DEBUGLOG_0(Adapter, E1000G_WARN_LEVEL, "Cound not allocate memory for Rx SwPacket\n"); return (NULL); } rx_buf = packet->rx_buf; switch (e1000g_dma_type) { #ifdef __sparc case USE_DVMA: mystat = e1000g_alloc_dvma_buffer(Adapter, rx_buf, Adapter->rx_buffer_size); break; #endif case USE_DMA: mystat = e1000g_alloc_dma_buffer(Adapter, rx_buf, Adapter->rx_buffer_size, p_dma_attr); break; default: ASSERT(B_FALSE); break; } if (mystat != DDI_SUCCESS) { if (packet != NULL) kmem_free(packet, sizeof (rx_sw_packet_t)); E1000G_DEBUGLOG_0(Adapter, E1000G_WARN_LEVEL, "Failed to allocate Rx buffer\n"); return (NULL); } rx_buf->size -= E1000G_IPALIGNROOM; rx_buf->address += E1000G_IPALIGNROOM; rx_buf->dma_address += E1000G_IPALIGNROOM; packet->rx_ring = (caddr_t)rx_ring; packet->free_rtn.free_func = e1000g_rxfree_func; packet->free_rtn.free_arg = (char *)packet; /* * esballoc is changed to desballoc which * is undocumented call but as per sun, * we can use it. It gives better efficiency. */ packet->mp = desballoc((unsigned char *) rx_buf->address - E1000G_IPALIGNROOM, rx_buf->size + E1000G_IPALIGNROOM, BPRI_MED, &packet->free_rtn); if (packet->mp != NULL) { packet->mp->b_rptr += E1000G_IPALIGNROOM; packet->mp->b_wptr += E1000G_IPALIGNROOM; } packet->dma_type = e1000g_dma_type; return (packet); } void e1000g_free_rx_sw_packet(p_rx_sw_packet_t packet) { dma_buffer_t *rx_buf; if (packet->mp != NULL) { freemsg(packet->mp); packet->mp = NULL; } rx_buf = packet->rx_buf; ASSERT(rx_buf->dma_handle != NULL); rx_buf->size += E1000G_IPALIGNROOM; rx_buf->address -= E1000G_IPALIGNROOM; switch (packet->dma_type) { #ifdef __sparc case USE_DVMA: e1000g_free_dvma_buffer(rx_buf); break; #endif case USE_DMA: e1000g_free_dma_buffer(rx_buf); break; default: ASSERT(B_FALSE); break; } packet->dma_type = USE_NONE; kmem_free(packet, sizeof (rx_sw_packet_t)); } static void e1000g_free_rx_packets(e1000g_rx_ring_t *rx_ring) { p_rx_sw_packet_t packet, next_packet, free_list; rw_enter(&e1000g_rx_detach_lock, RW_WRITER); free_list = NULL; packet = rx_ring->packet_area; for (; packet != NULL; packet = next_packet) { next_packet = packet->next; if (packet->flag == E1000G_RX_SW_SENDUP) { rx_ring->pending_count++; e1000g_mblks_pending++; packet->flag = E1000G_RX_SW_STOP; packet->next = rx_ring->pending_list; rx_ring->pending_list = packet; } else { packet->next = free_list; free_list = packet; } } rx_ring->packet_area = NULL; rw_exit(&e1000g_rx_detach_lock); packet = free_list; for (; packet != NULL; packet = next_packet) { next_packet = packet->next; ASSERT(packet->flag == E1000G_RX_SW_FREE); e1000g_free_rx_sw_packet(packet); } } static void e1000g_free_tx_packets(e1000g_tx_ring_t *tx_ring) { int j; struct e1000g *Adapter; p_tx_sw_packet_t packet; dma_buffer_t *tx_buf; Adapter = tx_ring->adapter; for (j = 0, packet = tx_ring->packet_area; j < Adapter->tx_freelist_num; j++, packet++) { if (packet == NULL) break; /* Free the Tx DMA handle for dynamical binding */ if (packet->tx_dma_handle != NULL) { switch (packet->dma_type) { #ifdef __sparc case USE_DVMA: dvma_release(packet->tx_dma_handle); break; #endif case USE_DMA: ddi_dma_free_handle(&packet->tx_dma_handle); break; default: ASSERT(B_FALSE); break; } packet->tx_dma_handle = NULL; } else { /* * If the dma handle is NULL, then we don't * need to check the packets left. For they * have not been initialized or have been freed. */ break; } tx_buf = packet->tx_buf; switch (packet->dma_type) { #ifdef __sparc case USE_DVMA: e1000g_free_dvma_buffer(tx_buf); break; #endif case USE_DMA: e1000g_free_dma_buffer(tx_buf); break; default: ASSERT(B_FALSE); break; } packet->dma_type = USE_NONE; } if (tx_ring->packet_area != NULL) { kmem_free(tx_ring->packet_area, TX_SW_PKT_AREA_SZ); tx_ring->packet_area = NULL; } } /* * e1000g_release_dma_resources - release allocated DMA resources * * This function releases any pending buffers that has been * previously allocated */ void e1000g_release_dma_resources(struct e1000g *Adapter) { e1000g_free_descriptors(Adapter); e1000g_free_packets(Adapter); } void e1000g_set_fma_flags(struct e1000g *Adapter, int acc_flag, int dma_flag) { if (acc_flag) { e1000g_desc_acc_attr.devacc_attr_access = DDI_FLAGERR_ACC; } else { e1000g_desc_acc_attr.devacc_attr_access = DDI_DEFAULT_ACC; } if (dma_flag) { e1000g_tx_dma_attr.dma_attr_flags = DDI_DMA_FLAGERR; e1000g_buf_dma_attr.dma_attr_flags = DDI_DMA_FLAGERR; e1000g_desc_dma_attr.dma_attr_flags = DDI_DMA_FLAGERR; } else { e1000g_tx_dma_attr.dma_attr_flags = 0; e1000g_buf_dma_attr.dma_attr_flags = 0; e1000g_desc_dma_attr.dma_attr_flags = 0; } }