/*- * Copyright 2003-2011 Netlogic Microsystems (Netlogic). All rights * reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * THIS SOFTWARE IS PROVIDED BY Netlogic Microsystems ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL NETLOGIC OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. * * NETLOGIC_BSD */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include /* XLP can take upto 16K of FMN messages per hardware queue, as spill. * But, configuring all 16K causes the total spill memory to required * to blow upto 192MB for single chip configuration, and 768MB in four * chip configuration. Hence for now, we will setup the per queue spill * as 1K FMN messages. With this, the total spill memory needed for 1024 * hardware queues (with 12bytes per single entry FMN message) becomes * (1*1024)*12*1024queues = 12MB. For the four chip config, the memory * needed = 12 * 4 = 48MB. */ uint64_t nlm_cms_spill_total_messages = 1 * 1024; /* On a XLP832, we have the following FMN stations: * CPU stations: 8 * PCIE0 stations: 1 * PCIE1 stations: 1 * PCIE2 stations: 1 * PCIE3 stations: 1 * GDX stations: 1 * CRYPTO stations: 1 * RSA stations: 1 * CMP stations: 1 * POE stations: 1 * NAE stations: 1 * ================== * Total : 18 stations per chip * * For all 4 nodes, there are 18*4 = 72 FMN stations */ uint32_t nlm_cms_total_stations = 18 * 4 /*xlp_num_nodes*/; /** * Takes inputs as node, queue_size and maximum number of queues. * Calculates the base, start & end and returns the same for a * defined qid. * * The output queues are maintained in the internal output buffer * which is a on-chip SRAM structure. For the actial hardware * internal implementation, It is a structure which consists * of eight banks of 4096-entry x message-width SRAMs. The SRAM * implementation is designed to run at 1GHz with a 1-cycle read/write * access. A read/write transaction can be initiated for each bank * every cycle for a total of eight accesses per cycle. Successive * entries of the same output queue are placed in successive banks. * This is done to spread different read & write accesses to same/different * output queue over as many different banks as possible so that they * can be scheduled concurrently. Spreading the accesses to as many banks * as possible to maximize the concurrency internally is important for * achieving the desired peak throughput. This is done by h/w implementation * itself. * * Output queues are allocated from this internal output buffer by * software. The total capacity of the output buffer is 32K-entry. * Each output queue can be sized from 32-entry to 1024-entry in * increments of 32-entry. This is done by specifying a Start & a * End pointer: pointers to the first & last 32-entry chunks allocated * to the output queue. * * To optimize the storage required for 1024 OQ pointers, the upper 5-bits * are shared by the Start & the End pointer. The side-effect of this * optimization is that an OQ can't cross a 1024-entry boundary. Also, the * lower 5-bits don't need to be specified in the Start & the End pointer * as the allocation is in increments of 32-entries. * * Queue occupancy is tracked by a Head & a Tail pointer. Tail pointer * indicates the location to which next entry will be written & Head * pointer indicates the location from which next entry will be read. When * these pointers reach the top of the allocated space (indicated by the * End pointer), they are reset to the bottom of the allocated space * (indicated by the Start pointer). * * Output queue pointer information: * ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * * 14 10 9 5 4 0 * ------------------ * | base ptr | * ------------------ * ---------------- * | start ptr | * ---------------- * ---------------- * | end ptr | * ---------------- * ------------------------------------ * | head ptr | * ------------------------------------ * ------------------------------------ * | tail ptr | * ------------------------------------ * Note: * A total of 1024 segments can sit on one software-visible "bank" * of internal SRAM. Each segment contains 32 entries. Also note * that sw-visible "banks" are not the same as the actual internal * 8-bank implementation of hardware. It is an optimization of * internal access. * */ void nlm_cms_setup_credits(uint64_t base, int destid, int srcid, int credit) { uint32_t val; val = ((credit << 24) | (destid << 12) | (srcid << 0)); nlm_write_cms_reg(base, CMS_OUTPUTQ_CREDIT_CFG, val); } /* * base - CMS module base address for this node. * qid - is the output queue id otherwise called as vc id * spill_base - is the 40-bit physical address of spill memory. Must be 4KB aligned. * nsegs - No of segments where a "1" indicates 4KB. Spill size must be * a multiple of 4KB. */ int nlm_cms_alloc_spill_q(uint64_t base, int qid, uint64_t spill_base, int nsegs) { uint64_t queue_config; uint32_t spill_start; if (nsegs > CMS_MAX_SPILL_SEGMENTS_PER_QUEUE) { return 1; } queue_config = nlm_read_cms_reg(base,(CMS_OUTPUTQ_CONFIG(qid))); spill_start = ((spill_base >> 12) & 0x3F); /* Spill configuration */ queue_config = (((uint64_t)CMS_SPILL_ENA << 62) | (((spill_base >> 18) & 0x3FFFFF) << 27) | (spill_start + nsegs - 1) << 21 | (spill_start << 15)); nlm_write_cms_reg(base,(CMS_OUTPUTQ_CONFIG(qid)),queue_config); return 0; } uint64_t nlm_cms_get_onchip_queue (uint64_t base, int qid) { return nlm_read_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid)); } void nlm_cms_set_onchip_queue (uint64_t base, int qid, uint64_t val) { uint64_t rdval; rdval = nlm_read_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid)); rdval |= val; nlm_write_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid), rdval); } void nlm_cms_per_queue_level_intr(uint64_t base, int qid, int sub_type, int intr_val) { uint64_t val; val = nlm_read_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid)); val &= ~((0x7ULL << 56) | (0x3ULL << 54)); val |= (((uint64_t)sub_type<<54) | ((uint64_t)intr_val<<56)); nlm_write_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid), val); } void nlm_cms_per_queue_timer_intr(uint64_t base, int qid, int sub_type, int intr_val) { uint64_t val; val = nlm_read_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid)); val &= ~((0x7ULL << 51) | (0x3ULL << 49)); val |= (((uint64_t)sub_type<<49) | ((uint64_t)intr_val<<51)); nlm_write_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid), val); } /* returns 1 if interrupt has been generated for this output queue */ int nlm_cms_outputq_intr_check(uint64_t base, int qid) { uint64_t val; val = nlm_read_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid)); return ((val >> 59) & 0x1); } void nlm_cms_outputq_clr_intr(uint64_t base, int qid) { uint64_t val; val = nlm_read_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid)); val |= (1ULL<<59); nlm_write_cms_reg(base, CMS_OUTPUTQ_CONFIG(qid), val); } void nlm_cms_illegal_dst_error_intr(uint64_t base, int en) { uint64_t val; val = nlm_read_cms_reg(base, CMS_MSG_CONFIG); val |= (en<<8); nlm_write_cms_reg(base, CMS_MSG_CONFIG, val); } void nlm_cms_timeout_error_intr(uint64_t base, int en) { uint64_t val; val = nlm_read_cms_reg(base, CMS_MSG_CONFIG); val |= (en<<7); nlm_write_cms_reg(base, CMS_MSG_CONFIG, val); } void nlm_cms_biu_error_resp_intr(uint64_t base, int en) { uint64_t val; val = nlm_read_cms_reg(base, CMS_MSG_CONFIG); val |= (en<<6); nlm_write_cms_reg(base, CMS_MSG_CONFIG, val); } void nlm_cms_spill_uncorrectable_ecc_error_intr(uint64_t base, int en) { uint64_t val; val = nlm_read_cms_reg(base, CMS_MSG_CONFIG); val |= (en<<5) | (en<<3); nlm_write_cms_reg(base, CMS_MSG_CONFIG, val); } void nlm_cms_spill_correctable_ecc_error_intr(uint64_t base, int en) { uint64_t val; val = nlm_read_cms_reg(base, CMS_MSG_CONFIG); val |= (en<<4) | (en<<2); nlm_write_cms_reg(base, CMS_MSG_CONFIG, val); } void nlm_cms_outputq_uncorrectable_ecc_error_intr(uint64_t base, int en) { uint64_t val; val = nlm_read_cms_reg(base, CMS_MSG_CONFIG); val |= (en<<1); nlm_write_cms_reg(base, CMS_MSG_CONFIG, val); } void nlm_cms_outputq_correctable_ecc_error_intr(uint64_t base, int en) { uint64_t val; val = nlm_read_cms_reg(base, CMS_MSG_CONFIG); val |= (en<<0); nlm_write_cms_reg(base, CMS_MSG_CONFIG, val); } uint64_t nlm_cms_network_error_status(uint64_t base) { return nlm_read_cms_reg(base, CMS_MSG_ERR); } int nlm_cms_get_net_error_code(uint64_t err) { return ((err >> 12) & 0xf); } int nlm_cms_get_net_error_syndrome(uint64_t err) { return ((err >> 32) & 0x1ff); } int nlm_cms_get_net_error_ramindex(uint64_t err) { return ((err >> 44) & 0x7fff); } int nlm_cms_get_net_error_outputq(uint64_t err) { return ((err >> 16) & 0xfff); } /*========================= FMN Tracing related APIs ================*/ void nlm_cms_trace_setup(uint64_t base, int en, uint64_t trace_base, uint64_t trace_limit, int match_dstid_en, int dst_id, int match_srcid_en, int src_id, int wrap) { uint64_t val; nlm_write_cms_reg(base, CMS_TRACE_BASE_ADDR, trace_base); nlm_write_cms_reg(base, CMS_TRACE_LIMIT_ADDR, trace_limit); val = nlm_read_cms_reg(base, CMS_TRACE_CONFIG); val |= (((uint64_t)match_dstid_en << 39) | ((dst_id & 0xfff) << 24) | (match_srcid_en << 23) | ((src_id & 0xfff) << 8) | (wrap << 1) | (en << 0)); nlm_write_cms_reg(base, CMS_MSG_CONFIG, val); } void nlm_cms_endian_byte_swap (uint64_t base, int en) { nlm_write_cms_reg(base, CMS_MSG_ENDIAN_SWAP, en); }