Current Path : /sys/contrib/octeon-sdk/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/contrib/octeon-sdk/octeon-pci-console.c |
/***********************license start*************** * Copyright (c) 2003-2010 Cavium Networks (support@cavium.com). All rights * reserved. * * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * * 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. * * Neither the name of Cavium Networks nor the names of * its contributors may be used to endorse or promote products * derived from this software without specific prior written * permission. * This Software, including technical data, may be subject to U.S. export control * laws, including the U.S. Export Administration Act and its associated * regulations, and may be subject to export or import regulations in other * countries. * TO THE MAXIMUM EXTENT PERMITTED BY LAW, THE SOFTWARE IS PROVIDED "AS IS" * AND WITH ALL FAULTS AND CAVIUM NETWORKS MAKES NO PROMISES, REPRESENTATIONS OR * WARRANTIES, EITHER EXPRESS, IMPLIED, STATUTORY, OR OTHERWISE, WITH RESPECT TO * THE SOFTWARE, INCLUDING ITS CONDITION, ITS CONFORMITY TO ANY REPRESENTATION OR * DESCRIPTION, OR THE EXISTENCE OF ANY LATENT OR PATENT DEFECTS, AND CAVIUM * SPECIFICALLY DISCLAIMS ALL IMPLIED (IF ANY) WARRANTIES OF TITLE, * MERCHANTABILITY, NONINFRINGEMENT, FITNESS FOR A PARTICULAR PURPOSE, LACK OF * VIRUSES, ACCURACY OR COMPLETENESS, QUIET ENJOYMENT, QUIET POSSESSION OR * CORRESPONDENCE TO DESCRIPTION. THE ENTIRE RISK ARISING OUT OF USE OR * PERFORMANCE OF THE SOFTWARE LIES WITH YOU. ***********************license end**************************************/ #define CVMX_USE_1_TO_1_TLB_MAPPINGS 0 #ifdef CVMX_BUILD_FOR_LINUX_KERNEL #include <linux/kernel.h> #include <asm/octeon/cvmx.h> #include <asm/octeon/cvmx-spinlock.h> #include <asm/octeon/octeon-pci-console.h> #define MIN(a,b) min((a),(b)) #else #include "cvmx-platform.h" #include "cvmx.h" #include "cvmx-spinlock.h" #define MIN(a,b) (((a)<(b))?(a):(b)) #include "cvmx-bootmem.h" #include "octeon-pci-console.h" #endif #if defined(__linux__) && !defined(__KERNEL__) && !defined(OCTEON_TARGET) #include "octeon-pci.h" #endif /* The following code is only used in standalone CVMX applications. It does not apply for kernel or Linux programming */ #if defined(OCTEON_TARGET) && !defined(__linux__) static int cvmx_pci_console_num = 0; static int per_core_pci_consoles = 0; static uint64_t pci_console_desc_addr = 0; /* This function for simple executive internal use only - do not use in any application */ int __cvmx_pci_console_write (int fd, char *buf, int nbytes) { int console_num; if (fd >= 0x10000000) { console_num = fd & 0xFFFF; } else if (per_core_pci_consoles) { console_num = cvmx_get_core_num(); } else console_num = cvmx_pci_console_num; if (!pci_console_desc_addr) { const cvmx_bootmem_named_block_desc_t *block_desc = cvmx_bootmem_find_named_block(OCTEON_PCI_CONSOLE_BLOCK_NAME); pci_console_desc_addr = block_desc->base_addr; } return octeon_pci_console_write(pci_console_desc_addr, console_num, buf, nbytes, 0); } #endif #if !defined(CONFIG_OCTEON_U_BOOT) || (defined(CONFIG_OCTEON_U_BOOT) && defined(CFG_PCI_CONSOLE)) int octeon_pci_console_buffer_free_bytes(uint32_t buffer_size, uint32_t wr_idx, uint32_t rd_idx) { if (rd_idx >= buffer_size || wr_idx >= buffer_size) return -1; return (((buffer_size -1) - (wr_idx - rd_idx))%buffer_size); } int octeon_pci_console_buffer_avail_bytes(uint32_t buffer_size, uint32_t wr_idx, uint32_t rd_idx) { if (rd_idx >= buffer_size || wr_idx >= buffer_size) return -1; return (buffer_size - 1 - octeon_pci_console_buffer_free_bytes(buffer_size, wr_idx, rd_idx)); } #endif /* The following code is only used under Linux userspace when you are using CVMX */ #if defined(__linux__) && !defined(__KERNEL__) && !defined(OCTEON_TARGET) int octeon_pci_console_host_write(uint64_t console_desc_addr, unsigned int console_num, const char * buffer, int write_reqest_size, uint32_t flags) { if (!console_desc_addr) return -1; /* Get global pci console information and look up specific console structure. */ uint32_t num_consoles = octeon_read_mem32(console_desc_addr + offsetof(octeon_pci_console_desc_t, num_consoles)); // printf("Num consoles: %d, buf size: %d\n", num_consoles, console_buffer_size); if (console_num >= num_consoles) { printf("ERROR: attempting to read non-existant console: %d\n", console_num); return(-1); } uint64_t console_addr = octeon_read_mem64(console_desc_addr + offsetof(octeon_pci_console_desc_t, console_addr_array) + console_num *8); // printf("Console %d is at 0x%llx\n", console_num, (long long)console_addr); uint32_t console_buffer_size = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, buf_size)); /* Check to see if any data is available */ uint32_t rd_idx, wr_idx; uint64_t base_addr; base_addr = octeon_read_mem64(console_addr + offsetof(octeon_pci_console_t, input_base_addr)); rd_idx = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, input_read_index)); wr_idx = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, input_write_index)); // printf("Input base: 0x%llx, rd: %d(0x%x), wr: %d(0x%x)\n", (long long)base_addr, rd_idx, rd_idx, wr_idx, wr_idx); int bytes_to_write = octeon_pci_console_buffer_free_bytes(console_buffer_size, wr_idx, rd_idx); if (bytes_to_write <= 0) return bytes_to_write; bytes_to_write = MIN(bytes_to_write, write_reqest_size); /* Check to see if what we want to write is not contiguous, and limit ourselves to the contiguous block*/ if (wr_idx + bytes_to_write >= console_buffer_size) bytes_to_write = console_buffer_size - wr_idx; // printf("Attempting to write %d bytes, (buf size: %d)\n", bytes_to_write, write_reqest_size); octeon_pci_write_mem(base_addr + wr_idx, buffer, bytes_to_write, OCTEON_PCI_ENDIAN_64BIT_SWAP); octeon_write_mem32(console_addr + offsetof(octeon_pci_console_t, input_write_index), (wr_idx + bytes_to_write)%console_buffer_size); return bytes_to_write; } int octeon_pci_console_host_read(uint64_t console_desc_addr, unsigned int console_num, char * buffer, int buf_size, uint32_t flags) { if (!console_desc_addr) return -1; /* Get global pci console information and look up specific console structure. */ uint32_t num_consoles = octeon_read_mem32(console_desc_addr + offsetof(octeon_pci_console_desc_t, num_consoles)); // printf("Num consoles: %d, buf size: %d\n", num_consoles, console_buffer_size); if (console_num >= num_consoles) { printf("ERROR: attempting to read non-existant console: %d\n", console_num); return(-1); } uint64_t console_addr = octeon_read_mem64(console_desc_addr + offsetof(octeon_pci_console_desc_t, console_addr_array) + console_num *8); uint32_t console_buffer_size = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, buf_size)); // printf("Console %d is at 0x%llx\n", console_num, (long long)console_addr); /* Check to see if any data is available */ uint32_t rd_idx, wr_idx; uint64_t base_addr; base_addr = octeon_read_mem64(console_addr + offsetof(octeon_pci_console_t, output_base_addr)); rd_idx = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, output_read_index)); wr_idx = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, output_write_index)); // printf("Read buffer base: 0x%llx, rd: %d(0x%x), wr: %d(0x%x)\n", (long long)base_addr, rd_idx, rd_idx, wr_idx, wr_idx); int bytes_to_read = octeon_pci_console_buffer_avail_bytes(console_buffer_size, wr_idx, rd_idx); if (bytes_to_read <= 0) return bytes_to_read; bytes_to_read = MIN(bytes_to_read, buf_size); /* Check to see if what we want to read is not contiguous, and limit ourselves to the contiguous block*/ if (rd_idx + bytes_to_read >= console_buffer_size) bytes_to_read = console_buffer_size - rd_idx; octeon_pci_read_mem(buffer, base_addr + rd_idx, bytes_to_read,OCTEON_PCI_ENDIAN_64BIT_SWAP); octeon_write_mem32(console_addr + offsetof(octeon_pci_console_t, output_read_index), (rd_idx + bytes_to_read)%console_buffer_size); return bytes_to_read; } int octeon_pci_console_host_write_avail(uint64_t console_desc_addr, unsigned int console_num) { if (!console_desc_addr) return -1; /* Get global pci console information and look up specific console structure. */ uint32_t num_consoles = octeon_read_mem32(console_desc_addr + offsetof(octeon_pci_console_desc_t, num_consoles)); // printf("Num consoles: %d, buf size: %d\n", num_consoles, console_buffer_size); if (console_num >= num_consoles) { printf("ERROR: attempting to read non-existant console: %d\n", console_num); return -1; } uint64_t console_addr = octeon_read_mem64(console_desc_addr + offsetof(octeon_pci_console_desc_t, console_addr_array) + console_num *8); // printf("Console %d is at 0x%llx\n", console_num, (long long)console_addr); uint32_t console_buffer_size = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, buf_size)); /* Check to see if any data is available */ uint32_t rd_idx, wr_idx; uint64_t base_addr; base_addr = octeon_read_mem64(console_addr + offsetof(octeon_pci_console_t, input_base_addr)); rd_idx = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, input_read_index)); wr_idx = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, input_write_index)); // printf("Input base: 0x%llx, rd: %d(0x%x), wr: %d(0x%x)\n", (long long)base_addr, rd_idx, rd_idx, wr_idx, wr_idx); return octeon_pci_console_buffer_free_bytes(console_buffer_size, wr_idx, rd_idx); } int octeon_pci_console_host_read_avail(uint64_t console_desc_addr, unsigned int console_num) { if (!console_desc_addr) return -1; /* Get global pci console information and look up specific console structure. */ uint32_t num_consoles = octeon_read_mem32(console_desc_addr + offsetof(octeon_pci_console_desc_t, num_consoles)); // printf("Num consoles: %d, buf size: %d\n", num_consoles, console_buffer_size); if (console_num >= num_consoles) { printf("ERROR: attempting to read non-existant console: %d\n", console_num); return(-1); } uint64_t console_addr = octeon_read_mem64(console_desc_addr + offsetof(octeon_pci_console_desc_t, console_addr_array) + console_num *8); uint32_t console_buffer_size = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, buf_size)); // printf("Console %d is at 0x%llx\n", console_num, (long long)console_addr); /* Check to see if any data is available */ uint32_t rd_idx, wr_idx; uint64_t base_addr; base_addr = octeon_read_mem64(console_addr + offsetof(octeon_pci_console_t, output_base_addr)); rd_idx = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, output_read_index)); wr_idx = octeon_read_mem32(console_addr + offsetof(octeon_pci_console_t, output_write_index)); // printf("Read buffer base: 0x%llx, rd: %d(0x%x), wr: %d(0x%x)\n", (long long)base_addr, rd_idx, rd_idx, wr_idx, wr_idx); return octeon_pci_console_buffer_avail_bytes(console_buffer_size, wr_idx, rd_idx); } #endif /* TARGET_HOST */ /* This code is only available in a kernel or CVMX standalone. It can't be used from userspace */ #if (!defined(CONFIG_OCTEON_U_BOOT) && (!defined(__linux__) || defined(__KERNEL__))) || (defined(CONFIG_OCTEON_U_BOOT) && defined(CFG_PCI_CONSOLE)) static octeon_pci_console_t *octeon_pci_console_get_ptr(uint64_t console_desc_addr, unsigned int console_num) { octeon_pci_console_desc_t *cons_desc_ptr; if (!console_desc_addr) return NULL; cons_desc_ptr = (octeon_pci_console_desc_t *)cvmx_phys_to_ptr(console_desc_addr); if (console_num >= cons_desc_ptr->num_consoles) return NULL; return (octeon_pci_console_t *)cvmx_phys_to_ptr(cons_desc_ptr->console_addr_array[console_num]); } int octeon_pci_console_write(uint64_t console_desc_addr, unsigned int console_num, const char * buffer, int bytes_to_write, uint32_t flags) { octeon_pci_console_t *cons_ptr; cvmx_spinlock_t *lock; int bytes_available; char *buf_ptr; int bytes_written; cons_ptr = octeon_pci_console_get_ptr(console_desc_addr, console_num); if (!cons_ptr) return -1; lock = (cvmx_spinlock_t *)&cons_ptr->lock; buf_ptr = (char*)cvmx_phys_to_ptr(cons_ptr->output_base_addr); bytes_written = 0; cvmx_spinlock_lock(lock); while (bytes_to_write > 0) { bytes_available = octeon_pci_console_buffer_free_bytes(cons_ptr->buf_size, cons_ptr->output_write_index, cons_ptr->output_read_index); // printf("Console %d has %d bytes available for writes\n", console_num, bytes_available); if (bytes_available > 0) { int write_size = MIN(bytes_available, bytes_to_write); /* Limit ourselves to what we can output in a contiguous block */ if (cons_ptr->output_write_index + write_size >= cons_ptr->buf_size) write_size = cons_ptr->buf_size - cons_ptr->output_write_index; memcpy(buf_ptr + cons_ptr->output_write_index, buffer + bytes_written, write_size); CVMX_SYNCW; /* Make sure data is visible before changing write index */ cons_ptr->output_write_index = (cons_ptr->output_write_index + write_size)%cons_ptr->buf_size; bytes_to_write -= write_size; bytes_written += write_size; } else if (bytes_available == 0) { /* Check to see if we should wait for room, or return after a partial write */ if (flags & OCT_PCI_CON_FLAG_NONBLOCK) goto done; cvmx_wait(1000000); /* Delay if we are spinning */ } else { bytes_written = -1; goto done; } } done: cvmx_spinlock_unlock(lock); return(bytes_written); } int octeon_pci_console_read(uint64_t console_desc_addr, unsigned int console_num, char * buffer, int buffer_size, uint32_t flags) { int bytes_available; char *buf_ptr; cvmx_spinlock_t *lock; int bytes_read; int read_size; octeon_pci_console_t *cons_ptr = octeon_pci_console_get_ptr(console_desc_addr, console_num); if (!cons_ptr) return -1; buf_ptr = (char*)cvmx_phys_to_ptr(cons_ptr->input_base_addr); bytes_available = octeon_pci_console_buffer_avail_bytes(cons_ptr->buf_size, cons_ptr->input_write_index, cons_ptr->input_read_index); if (bytes_available < 0) return bytes_available; lock = (cvmx_spinlock_t *)&cons_ptr->lock; cvmx_spinlock_lock(lock); if (!(flags & OCT_PCI_CON_FLAG_NONBLOCK)) { /* Wait for some data to be available */ while (0 == (bytes_available = octeon_pci_console_buffer_avail_bytes(cons_ptr->buf_size, cons_ptr->input_write_index, cons_ptr->input_read_index))) cvmx_wait(1000000); } bytes_read = 0; // printf("Console %d has %d bytes available for writes\n", console_num, bytes_available); /* Don't overflow the buffer passed to us */ read_size = MIN(bytes_available, buffer_size); /* Limit ourselves to what we can input in a contiguous block */ if (cons_ptr->input_read_index + read_size >= cons_ptr->buf_size) read_size = cons_ptr->buf_size - cons_ptr->input_read_index; memcpy(buffer, buf_ptr + cons_ptr->input_read_index, read_size); cons_ptr->input_read_index = (cons_ptr->input_read_index + read_size)%cons_ptr->buf_size; bytes_read += read_size; cvmx_spinlock_unlock(lock); return(bytes_read); } int octeon_pci_console_write_avail(uint64_t console_desc_addr, unsigned int console_num) { int bytes_available; octeon_pci_console_t *cons_ptr = octeon_pci_console_get_ptr(console_desc_addr, console_num); if (!cons_ptr) return -1; bytes_available = octeon_pci_console_buffer_free_bytes(cons_ptr->buf_size, cons_ptr->input_write_index, cons_ptr->input_read_index); if (bytes_available >= 0) return(bytes_available); else return 0; } int octeon_pci_console_read_avail(uint64_t console_desc_addr, unsigned int console_num) { int bytes_available; octeon_pci_console_t *cons_ptr = octeon_pci_console_get_ptr(console_desc_addr, console_num); if (!cons_ptr) return -1; bytes_available = octeon_pci_console_buffer_avail_bytes(cons_ptr->buf_size, cons_ptr->input_write_index, cons_ptr->input_read_index); if (bytes_available >= 0) return(bytes_available); else return 0; } #endif /* This code can only be used in the bootloader */ #if defined(CONFIG_OCTEON_U_BOOT) && defined(CFG_PCI_CONSOLE) #define DDR0_TOP 0x10000000 #define DDR2_BASE 0x20000000 uint64_t octeon_pci_console_init(int num_consoles, int buffer_size) { octeon_pci_console_desc_t *cons_desc_ptr; octeon_pci_console_t *cons_ptr; /* Compute size required for pci console structure */ int alloc_size = num_consoles * (buffer_size * 2 + sizeof(octeon_pci_console_t) + sizeof(uint64_t)) + sizeof(octeon_pci_console_desc_t); /* Allocate memory for the consoles. This must be in the range addresssible by the bootloader. ** Try to do so in a manner which minimizes fragmentation. We try to put it at the top of DDR0 or bottom of ** DDR2 first, and only do generic allocation if those fail */ int64_t console_block_addr = cvmx_bootmem_phy_named_block_alloc(alloc_size, DDR0_TOP - alloc_size - 128, DDR0_TOP, 128, OCTEON_PCI_CONSOLE_BLOCK_NAME, CVMX_BOOTMEM_FLAG_END_ALLOC); if (console_block_addr < 0) console_block_addr = cvmx_bootmem_phy_named_block_alloc(alloc_size, DDR2_BASE + 1, DDR2_BASE + alloc_size + 128, 128, OCTEON_PCI_CONSOLE_BLOCK_NAME, CVMX_BOOTMEM_FLAG_END_ALLOC); if (console_block_addr < 0) console_block_addr = cvmx_bootmem_phy_named_block_alloc(alloc_size, 0, 0x7fffffff, 128, OCTEON_PCI_CONSOLE_BLOCK_NAME, CVMX_BOOTMEM_FLAG_END_ALLOC); if (console_block_addr < 0) return 0; cons_desc_ptr = (void *)(uint32_t)console_block_addr; memset(cons_desc_ptr, 0, alloc_size); /* Clear entire alloc'ed memory */ cons_desc_ptr->lock = 1; /* initialize as locked until we are done */ CVMX_SYNCW; cons_desc_ptr->num_consoles = num_consoles; cons_desc_ptr->flags = 0; cons_desc_ptr->major_version = OCTEON_PCI_CONSOLE_MAJOR_VERSION; cons_desc_ptr->minor_version = OCTEON_PCI_CONSOLE_MINOR_VERSION; int i; uint64_t avail_addr = console_block_addr + sizeof(octeon_pci_console_desc_t) + num_consoles * sizeof(uint64_t); for (i = 0; i < num_consoles;i++) { cons_desc_ptr->console_addr_array[i] = avail_addr; cons_ptr = (void *)(uint32_t)cons_desc_ptr->console_addr_array[i]; avail_addr += sizeof(octeon_pci_console_t); cons_ptr->input_base_addr = avail_addr; avail_addr += buffer_size; cons_ptr->output_base_addr = avail_addr; avail_addr += buffer_size; cons_ptr->buf_size = buffer_size; } CVMX_SYNCW; cons_desc_ptr->lock = 0; return console_block_addr; } #endif