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#include <stdio.h>
#include <string.h>
#include <strings.h>
#include <stdlib.h>
#include <stdint.h>
#include <stdarg.h>
#include <fcntl.h>
#include <unistd.h>
#include <sys/ioctl.h>
#include <sys/mman.h>
#include <arpa/inet.h>
#include <errno.h>
#include <assert.h>
#include "pci.h"
#include "bank.h"
#include "tools.h"
#include "error.h"
int pcilib_add_registers(pcilib_t *ctx, size_t n, const pcilib_register_description_t *registers) {
// DS: What we are doing if register exists?
pcilib_register_description_t *regs;
size_t size;
if (!n) {
for (n = 0; registers[n].bits; n++);
}
if ((ctx->num_reg + n + 1) > ctx->alloc_reg) {
for (size = ctx->alloc_reg; size < 2 * (n + ctx->num_reg + 1); size<<=1);
regs = (pcilib_register_description_t*)realloc(ctx->registers, size * sizeof(pcilib_register_description_t));
if (!regs) return PCILIB_ERROR_MEMORY;
ctx->registers = regs;
ctx->model_info.registers = regs;
ctx->alloc_reg = size;
}
memcpy(ctx->registers + ctx->num_reg, registers, n * sizeof(pcilib_register_description_t));
memset(ctx->registers + ctx->num_reg + n, 0, sizeof(pcilib_register_description_t));
ctx->num_reg += n;
return 0;
}
static int pcilib_read_register_space_internal(pcilib_t *ctx, pcilib_register_bank_t bank, pcilib_register_addr_t addr, size_t n, pcilib_register_size_t offset, pcilib_register_size_t bits, pcilib_register_value_t *buf) {
int err;
size_t i;
pcilib_register_bank_context_t *bctx = ctx->bank_ctx[bank];
const pcilib_register_protocol_api_description_t *bapi = bctx->api;
const pcilib_register_bank_description_t *b = bctx->bank;
int access = b->access / 8;
assert(bits < 8 * sizeof(pcilib_register_value_t));
if (!bapi->read) {
pcilib_error("Used register protocol does not define a way to read register value");
return PCILIB_ERROR_NOTSUPPORTED;
}
if (((addr + n) > b->size)||(((addr + n) == b->size)&&(bits))) {
if ((b->format)&&(strchr(b->format, 'x')))
pcilib_error("Accessing register (%u regs at addr 0x%x) out of register space (%u registers total)", bits?(n+1):n, addr, b->size);
else
pcilib_error("Accessing register (%u regs at addr %u) out of register space (%u registers total)", bits?(n+1):n, addr, b->size);
return PCILIB_ERROR_OUTOFRANGE;
}
//err = pcilib_init_register_banks(ctx);
//if (err) return err;
//n += bits / b->access;
//bits %= b->access;
for (i = 0; i < n; i++) {
err = bapi->read(ctx, bctx, addr + i * access, buf + i);
if (err) break;
}
if ((bits > 0)&&(!err)) {
pcilib_register_value_t val = 0;
err = bapi->read(ctx, bctx, addr + n * access, &val);
val = (val >> offset)&BIT_MASK(bits);
memcpy(buf + n, &val, sizeof(pcilib_register_value_t));
}
return err;
}
int pcilib_read_register_space(pcilib_t *ctx, const char *bank, pcilib_register_addr_t addr, size_t n, pcilib_register_value_t *buf) {
pcilib_register_bank_t bank_id = pcilib_find_register_bank(ctx, bank);
if (bank_id == PCILIB_REGISTER_BANK_INVALID) {
if (bank) pcilib_error("Invalid register bank is specified (%s)", bank);
else pcilib_error("Register bank should be specified");
return PCILIB_ERROR_INVALID_BANK;
}
return pcilib_read_register_space_internal(ctx, bank_id, addr, n, 0, 0, buf);
}
int pcilib_read_register_by_id(pcilib_t *ctx, pcilib_register_t reg, pcilib_register_value_t *value) {
int err;
size_t i, n;
pcilib_register_size_t bits;
pcilib_register_value_t res;
pcilib_register_bank_t bank;
const pcilib_register_description_t *r;
const pcilib_register_bank_description_t *b;
const pcilib_model_description_t *model_info = pcilib_get_model_description(ctx);
r = model_info->registers + reg;
bank = pcilib_find_register_bank_by_addr(ctx, r->bank);
if (bank == PCILIB_REGISTER_BANK_INVALID) return PCILIB_ERROR_INVALID_BANK;
b = model_info->banks + bank;
n = r->bits / b->access;
bits = r->bits % b->access;
pcilib_register_value_t buf[n + 1];
err = pcilib_read_register_space_internal(ctx, bank, r->addr, n, r->offset, bits, buf);
if ((b->endianess == PCILIB_BIG_ENDIAN)||((b->endianess == PCILIB_HOST_ENDIAN)&&(ntohs(1) == 1))) {
pcilib_error("Big-endian byte order support is not implemented");
return PCILIB_ERROR_NOTSUPPORTED;
} else {
res = 0;
if (bits) ++n;
for (i = 0; i < n; i++) {
res |= buf[i] << (i * b->access);
}
}
*value = res;
return err;
}
int pcilib_read_register(pcilib_t *ctx, const char *bank, const char *regname, pcilib_register_value_t *value) {
int reg;
reg = pcilib_find_register(ctx, bank, regname);
if (reg < 0) {
pcilib_error("Register (%s) is not found", regname);
return PCILIB_ERROR_NOTFOUND;
}
return pcilib_read_register_by_id(ctx, reg, value);
}
static int pcilib_write_register_space_internal(pcilib_t *ctx, pcilib_register_bank_t bank, pcilib_register_addr_t addr, size_t n, pcilib_register_size_t offset, pcilib_register_size_t bits, pcilib_register_value_t rwmask, pcilib_register_value_t *buf) {
int err;
size_t i;
pcilib_register_bank_context_t *bctx = ctx->bank_ctx[bank];
const pcilib_register_protocol_api_description_t *bapi = bctx->api;
const pcilib_register_bank_description_t *b = bctx->bank;
int access = b->access / 8;
assert(bits < 8 * sizeof(pcilib_register_value_t));
if (!bapi->write) {
pcilib_error("Used register protocol does not define a way to write value into the register");
return PCILIB_ERROR_NOTSUPPORTED;
}
if (((addr + n) > b->size)||(((addr + n) == b->size)&&(bits))) {
if ((b->format)&&(strchr(b->format, 'x')))
pcilib_error("Accessing register (%u regs at addr 0x%x) out of register space (%u registers total)", bits?(n+1):n, addr, b->size);
else
pcilib_error("Accessing register (%u regs at addr %u) out of register space (%u registers total)", bits?(n+1):n, addr, b->size);
return PCILIB_ERROR_OUTOFRANGE;
}
//err = pcilib_init_register_banks(ctx);
//if (err) return err;
//n += bits / b->access;
//bits %= b->access;
for (i = 0; i < n; i++) {
err = bapi->write(ctx, bctx, addr + i * access, buf[i]);
if (err) break;
}
if ((bits > 0)&&(!err)) {
pcilib_register_value_t val = (buf[n]&BIT_MASK(bits))<<offset;
pcilib_register_value_t mask = BIT_MASK(bits)<<offset;
if (~mask&rwmask) {
pcilib_register_value_t rval;
if (!bapi->read) {
pcilib_error("Used register protocol does not define a way to read register. Therefore, it is only possible to write a full bank word, not partial as required by the accessed register");
return PCILIB_ERROR_NOTSUPPORTED;
}
err = bapi->read(ctx, bctx, addr + n * access, &rval);
if (err) return err;
val |= (rval & rwmask & ~mask);
}
err = bapi->write(ctx, bctx, addr + n * access, val);
}
return err;
}
int pcilib_write_register_space(pcilib_t *ctx, const char *bank, pcilib_register_addr_t addr, size_t n, pcilib_register_value_t *buf) {
pcilib_register_bank_t bank_id = pcilib_find_register_bank(ctx, bank);
if (bank_id == PCILIB_REGISTER_BANK_INVALID) {
if (bank) pcilib_error("Invalid register bank is specified (%s)", bank);
else pcilib_error("Register bank should be specified");
return PCILIB_ERROR_INVALID_BANK;
}
return pcilib_write_register_space_internal(ctx, bank_id, addr, n, 0, 0, 0, buf);
}
int pcilib_write_register_by_id(pcilib_t *ctx, pcilib_register_t reg, pcilib_register_value_t value) {
int err;
size_t i, n;
pcilib_register_size_t bits;
pcilib_register_bank_t bank;
pcilib_register_value_t res;
const pcilib_register_description_t *r;
const pcilib_register_bank_description_t *b;
const pcilib_model_description_t *model_info = pcilib_get_model_description(ctx);
r = model_info->registers + reg;
bank = pcilib_find_register_bank_by_addr(ctx, r->bank);
if (bank == PCILIB_REGISTER_BANK_INVALID) return PCILIB_ERROR_INVALID_BANK;
b = model_info->banks + bank;
n = r->bits / b->access;
bits = r->bits % b->access;
pcilib_register_value_t buf[n + 1];
memset(buf, 0, (n + 1) * sizeof(pcilib_register_value_t));
if ((b->endianess == PCILIB_BIG_ENDIAN)||((b->endianess == PCILIB_HOST_ENDIAN)&&(ntohs(1) == 1))) {
pcilib_error("Big-endian byte order support is not implemented");
return PCILIB_ERROR_NOTSUPPORTED;
} else {
if (b->access == sizeof(pcilib_register_value_t) * 8) {
buf[0] = value;
} else {
for (i = 0, res = value; (res > 0)&&(i <= n); ++i) {
buf[i] = res & BIT_MASK(b->access);
res >>= b->access;
}
if (res) {
pcilib_error("Value %i is too big to fit in the register %s", value, r->name);
return PCILIB_ERROR_OUTOFRANGE;
}
}
}
err = pcilib_write_register_space_internal(ctx, bank, r->addr, n, r->offset, bits, r->rwmask, buf);
return err;
}
int pcilib_write_register(pcilib_t *ctx, const char *bank, const char *regname, pcilib_register_value_t value) {
int reg;
reg = pcilib_find_register(ctx, bank, regname);
if (reg < 0) {
pcilib_error("Register (%s) is not found", regname);
return PCILIB_ERROR_NOTFOUND;
}
return pcilib_write_register_by_id(ctx, reg, value);
}
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