/* See LICENSE file for copyright and license details. */
#include "state.h"
#include "util.h"
#include <inttypes.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
/**
* The name of the process
*/
char *restrict argv0; /* do not marshal */
/**
* The real pathname of the process's binary,
* `NULL` if `argv0` is satisfactory
*/
char *restrict argv0_real = NULL;
/**
* Array of all outputs
*/
struct output *restrict outputs = NULL;
/**
* The nubmer of elements in `outputs`
*/
size_t outputs_n = 0;
/**
* The server socket's file descriptor
*/
int socketfd = -1;
/**
* Has the process receive a signal
* telling it to re-execute?
*/
volatile sig_atomic_t reexec = 0; /* do not marshal */
/**
* Has the process receive a signal
* telling it to terminate?
*/
volatile sig_atomic_t terminate = 0; /* do not marshal */
/**
* Has the process receive a to
* disconnect from or reconnect to
* the site? 1 if disconnect, 2 if
* reconnect, 0 otherwise.
*/
volatile sig_atomic_t connection = 0;
/**
* List of all client's file descriptors
*
* Unused slots, with index less than `connections_used`,
* should have the value -1 (negative)
*/
int *restrict connections = NULL;
/**
* The number of elements allocated for `connections`
*/
size_t connections_alloc = 0;
/**
* The index of the first unused slot in `connections`
*/
size_t connections_ptr = 0;
/**
* The index of the last used slot in `connections`, plus 1
*/
size_t connections_used = 0;
/**
* The clients' connections' inbound-message buffers
*/
struct message *restrict inbound = NULL;
/**
* The clients' connections' outbound-message buffers
*/
struct ring *restrict outbound = NULL;
/**
* Is the server connect to the display?
*
* Set to true before the initial connection
*/
int connected = 1;
/**
* The adjustment method, -1 for automatic
*/
int method = -1;
/**
* The site's name, may be `NULL`
*/
char *restrict sitename = NULL;
/**
* The libgamma site state
*/
struct libgamma_site_state site; /* do not marshal */
/**
* The libgamma partition states
*/
struct libgamma_partition_state *restrict partitions = NULL; /* do not marshal */
/**
* The libgamma CRTC states
*/
struct libgamma_crtc_state *restrict crtcs = NULL; /* do not marshal */
/**
* Preserve gamma ramps at priority 0?
*/
int preserve = 0;
/**
* As part of a state dump, dump one or two gamma ramp-trios
*
* @param left The left ramps
* @param right The right ramps
* @param depth The gamma ramp type/depth
* @param have_right Print right ramps?
* @param indent Print indent
*/
static void
ramps_dump(union gamma_ramps *left, union gamma_ramps *right, signed depth, int have_right, const char *indent)
{
#define STRINGISE(SIDE, CH, N, BUF)\
do {\
if (!SIDE || !SIDE->u8.CH) {\
strcpy(BUF, "null");\
} else if (i < N) {\
switch (depth) {\
case -2: snprintf(BUF, sizeof(BUF), "%lf", SIDE->d.CH[i]); break;\
case -1: snprintf(BUF, sizeof(BUF), "%f", (double)(SIDE->f.CH[i])); break;\
case 8: snprintf(BUF, sizeof(BUF), "%02" PRIx8, SIDE->u8.CH[i]); break;\
case 16: snprintf(BUF, sizeof(BUF), "%04" PRIx16, SIDE->u16.CH[i]); break;\
case 32: snprintf(BUF, sizeof(BUF), "%08" PRIx32, SIDE->u32.CH[i]); break;\
case 64: snprintf(BUF, sizeof(BUF), "%16" PRIx64, SIDE->u64.CH[i]); break;\
default:\
strcpy(BUF, "corrupt state");\
break;\
}\
}\
} while (0)
char lr[320], lg[320], lb[320], rr[320], rg[320], rb[320];
size_t rn = left ? left->u8.red_size : right ? right->u8.red_size : 0;
size_t gn = left ? left->u8.green_size : right ? right->u8.green_size : 0;
size_t bn = left ? left->u8.blue_size : right ? right->u8.blue_size : 0;
size_t i, n = rn > gn ? rn : gn;
n = n > bn ? n : bn;
for (i = 0; i < n; i++) {
*lr = *lg = *lb = *rr = *rg = *rb = '\0';
STRINGISE(left, red, rn, lr);
STRINGISE(left, green, gn, lg);
STRINGISE(left, blue, bn, lb);
if (have_right) {
STRINGISE(right, red, rn, rr);
STRINGISE(right, green, gn, rg);
STRINGISE(right, blue, bn, rb);
}
if (have_right)
fprintf(stderr, "%s%zu: %s, %s, %s :: %s, %s, %s\n", indent, i, lr, lg, lb, rr, rg, rb);
else
fprintf(stderr, "%s%zu: %s, %s, %s\n", indent, i, lr, lg, lb);
}
}
/**
* Dump the state to stderr
*/
void
state_dump(void)
{
size_t i, j;
struct output *restrict out;
const char *str;
struct filter *restrict filter;
union gamma_ramps left;
size_t depth;
fprintf(stderr, "argv0: %s\n", argv0 ? argv0 : "(null)");
fprintf(stderr, "Realpath of argv0: %s\n", argv0_real ? argv0_real : "(null)");
fprintf(stderr, "Calibrations preserved: %s\n", preserve ? "yes" : "no");
fprintf(stderr, "Connected: %s\n", connected ? "yes" : "no");
fprintf(stderr, "Socket FD: %i\n", socketfd);
fprintf(stderr, "Re-execution pending: %s\n", reexec ? "yes" : "no");
fprintf(stderr, "Termination pending: %s\n", terminate ? "yes" : "no");
if (0 <= connection && connection <= 2)
fprintf(stderr, "Pending connection change: %s\n",
connection == 0 ? "none" : connection == 1 ? "disconnect" : "reconnect");
else
fprintf(stderr, "Pending connection change: %i (CORRUPT STATE)\n", connection);
fprintf(stderr, "Adjustment method: %i\n", method);
fprintf(stderr, "Site name: %s\n", sitename ? sitename : "(automatic)");
fprintf(stderr, "Clients:\n");
fprintf(stderr, " Next empty slot: %zu\n", connections_ptr);
fprintf(stderr, " Initialised slots: %zu\n", connections_used);
fprintf(stderr, " Allocated slots: %zu\n", connections_alloc);
if (!connections) {
fprintf(stderr, " File descriptor array is null\n");
} else {
for (i = 0; i < connections_used; i++) {
if (connections[i] < 0) {
fprintf(stderr, " Slot %zu: empty\n", i);
continue;
}
fprintf(stderr, " Slot %zu:\n", i);
fprintf(stderr, " File descriptor: %i\n", connections[i]);
if (!inbound) {
fprintf(stderr, " Inbound message array is null\n");
} else {
fprintf(stderr, " Inbound message:\n");
fprintf(stderr, " Header array: %s\n", inbound[i].headers ? "non-null" : "null");
fprintf(stderr, " Headers: %zu\n", inbound[i].header_count);
fprintf(stderr, " Payload buffer: %s\n", inbound[i].payload ? "non-null" : "null");
fprintf(stderr, " Payload size: %zu\n", inbound[i].payload_size);
fprintf(stderr, " Payload write pointer: %zu\n", inbound[i].payload_ptr);
fprintf(stderr, " Message buffer: %s\n", inbound[i].buffer ? "non-null" : "null");
fprintf(stderr, " Message buffer size: %zu\n", inbound[i].buffer_size);
fprintf(stderr, " Message buffer write pointer: %zu\n", inbound[i].buffer_ptr);
fprintf(stderr, " Read stage: %i\n", inbound[i].stage);
}
if (!outbound) {
fprintf(stderr, " Outbound message array is null\n");
} else {
fprintf(stderr, " Ring buffer: %s\n", outbound[i].buffer ? "non-null" : "null");
fprintf(stderr, " Head: %zu\n", outbound[i].end);
fprintf(stderr, " Tail: %zu\n", outbound[i].start);
fprintf(stderr, " Size: %zu\n", outbound[i].size);
}
}
}
fprintf(stderr, "Partition array: %s\n", partitions ? "non-null" : "null");
fprintf(stderr, "CRTC array: %s\n", crtcs ? "non-null" : "null");
fprintf(stderr, "Output:\n");
fprintf(stderr, " Output count: %zu\n", outputs_n);
if (!outputs) {
fprintf(stderr, " Output array is null\n");
} else {
for (i = 0; i < outputs_n; i++) {
out = outputs + i;
fprintf(stderr, " Output %zu:\n", i);
fprintf(stderr, " Depth: %i (%s)\n", out->depth,
out->depth == -1 ? "float" :
out->depth == -2 ? "double" :
out->depth == 8 ? "uint8_t" :
out->depth == 16 ? "uint16_t" :
out->depth == 32 ? "uint32_t" :
out->depth == 64 ? "uint64_t" : "CORRUPT STATE");
fprintf(stderr, " Gamma supported: %s (%u)\n",
out->supported == LIBGAMMA_YES ? "yes" :
out->supported == LIBGAMMA_NO ? "no" :
out->supported == LIBGAMMA_MAYBE ? "maybe" :
"CORRUPT STATE", out->supported);
fprintf(stderr, " Name is EDID: %s\n", out->name_is_edid ? "yes" : "no");
switch (out->colourspace) {
case COLOURSPACE_UNKNOWN: str = "unknown"; break;
case COLOURSPACE_SRGB: str = "sRGB with explicit gamut"; break;
case COLOURSPACE_SRGB_SANS_GAMUT: str = "sRGB with implicit gamut (actually illegal)"; break;
case COLOURSPACE_RGB: str = "RGB other than sRGB, with unknown gamut"; break;
case COLOURSPACE_RGB_SANS_GAMUT: str = "RGB other than sRGB, with listed gamut"; break;
case COLOURSPACE_NON_RGB: str = "Non-RGB multicolour"; break;
case COLOURSPACE_GREY: str = "Monochrome or singlecolour scale"; break;
default: str = "CORRUPT STATE"; break;
}
fprintf(stderr, " Colourspace: %s (%u)\n", str, out->colourspace);
if (out->colourspace == COLOURSPACE_SRGB || out->colourspace == COLOURSPACE_RGB) {
fprintf(stderr, " Red (x, y): (%u / 1024, %u / 1024)\n", out->red_x, out->red_y);
fprintf(stderr, " Green (x, y): (%u / 1024, %u / 1024)\n", out->green_x, out->green_y);
fprintf(stderr, " Blue (x, y): (%u / 1024, %u / 1024)\n", out->blue_x, out->blue_y);
fprintf(stderr, " White (x, y): (%u / 1024, %u / 1024)\n", out->white_x, out->white_y);
if (out->colourspace == COLOURSPACE_SRGB) {
fprintf(stderr, " Expected red (x, y): (655 / 1024, 338 / 1024)\n");
fprintf(stderr, " Expected green (x, y): (307 / 1024, 614 / 1024)\n");
fprintf(stderr, " Expected blue (x, y): (154 / 1024, 61 / 1024)\n");
fprintf(stderr, " Expected white (x, y): (320 / 1024, 337 / 1024)\n");
}
}
if (out->supported) {
fprintf(stderr, " Gamma ramp size:\n");
fprintf(stderr, " Red: %zu stops\n", out->red_size);
fprintf(stderr, " Green: %zu stops\n", out->green_size);
fprintf(stderr, " Blue: %zu stops\n", out->blue_size);
fprintf(stderr, " Total: %zu bytes\n", out->ramps_size);
fprintf(stderr, " Name: %s\n", out->name ? out->name : "(null)");
fprintf(stderr, " CRTC state: %s\n", out->crtc ? "non-null" : "null");
fprintf(stderr, " Saved gamma ramps (stop: red, green, blue):\n");
ramps_dump(&out->saved_ramps, NULL, out->depth, 0, " ");
fprintf(stderr, " Filter table:\n");
fprintf(stderr, " Filter count: %zu\n", out->table_size);
fprintf(stderr, " Slots allocated: %zu\n", out->table_alloc);
if (out->table_size > 0) {
if (!out->table_filters)
fprintf(stderr, " Filter table is null\n");
if (!out->table_sums)
fprintf(stderr, " Result table is null\n");
}
for (j = 0; j < out->table_size; j++) {
filter = out->table_filters ? out->table_filters + j : NULL;
fprintf(stderr, " Filter %zu:\n", j);
if (filter) {
if (filter->lifespan == LIFESPAN_UNTIL_DEATH)
fprintf(stderr, " Client FD: %i\n", filter->client);
switch (filter->lifespan) {
case LIFESPAN_REMOVE: str = "remove (ILLEGAL STATE)"; break;
case LIFESPAN_UNTIL_REMOVAL: str = "until-removal"; break;
case LIFESPAN_UNTIL_DEATH: str = "until-death"; break;
default: str = "CORRUPT STATE"; break;
}
fprintf(stderr, " Lifespan: %s (%u)\n", str, filter->lifespan);
fprintf(stderr, " Priority: %"PRIi64"\n", filter->priority);
fprintf(stderr, " Class: %s\n", filter->class ? filter->class : "(null)");
str = "yes";
if (!filter->class)
str = "no, is NULL";
else if (strchr(filter->class, '\n'))
str = "no, contains LF";
else if (!strstr(filter->class, "::"))
str = "no, does not contain \"::\"";
else if (!strstr(strstr(filter->class, "::") + 2, "::"))
str = "no, contains only one \"::\"";
else if (verify_utf8(filter->class) < 0)
str = "no, not UTF-8";
fprintf(stderr, " Class legal: %s\n", str);
if (!filter->ramps && filter->lifespan != LIFESPAN_REMOVE)
fprintf(stderr, " Ramps are NULL\n");
}
if (filter ? filter->lifespan != LIFESPAN_REMOVE : !!out->table_sums) {
switch (out->depth) {
case -2:
depth = sizeof(double);
break;
case -1:
depth = sizeof(float);
break;
case 8: case 16: case 32: case 64:
depth = (size_t)(out->depth) / 8;
break;
default:
goto corrupt_depth;
}
if (filter && filter->ramps) {
left.u8.red_size = out->red_size;
left.u8.green_size = out->green_size;
left.u8.blue_size = out->blue_size;
left.u8.red = filter->ramps;
left.u8.green = left.u8.red + out->red_size * depth;
left.u8.blue = left.u8.green + out->green_size * depth;
}
fprintf(stderr, " Ramps (stop: filter red, green, blue :: "
"composite red, geen, blue):\n");
ramps_dump((filter && filter->ramps) ? &left : NULL,
out->table_sums ? out->table_sums + j : NULL,
out->depth, 1, " ");
corrupt_depth:;
}
}
}
}
}
}
/**
* Destroy the state
*/
void
state_destroy(void)
{
size_t i;
for (i = 0; i < connections_used; i++) {
if (connections[i] >= 0) {
message_destroy(inbound + i);
ring_destroy(outbound + i);
}
}
free(inbound);
free(outbound);
free(connections);
if (outputs)
for (i = 0; i < outputs_n; i++)
output_destroy(outputs + i);
free(outputs);
if (crtcs)
for (i = 0; i < outputs_n; i++)
libgamma_crtc_destroy(crtcs + i);
free(crtcs);
if (partitions)
for (i = 0; i < site.partitions_available; i++)
libgamma_partition_destroy(partitions + i);
free(partitions);
libgamma_site_destroy(&site);
free(sitename);
}
#if defined(__clang__)
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Wcast-align"
#endif
/**
* Marshal the state
*
* @param buf Output buffer for the marshalled data,
* `NULL` to only measure how many bytes
* this buffer needs
* @return The number of marshalled bytes
*/
size_t
state_marshal(void *restrict buf)
{
size_t off = 0, i, n;
char *restrict bs = buf;
if (!argv0_real) {
if (bs)
bs[off] = '\0';
off += 1;
} else {
n = strlen(argv0_real) + 1;
if (bs)
memcpy(&bs[off], argv0_real, n);
off += n;
}
if (bs)
*(size_t *)&bs[off] = outputs_n;
off += sizeof(size_t);
for (i = 0; i < outputs_n; i++)
off += output_marshal(outputs + i, bs ? &bs[off] : NULL);
if (bs)
*(int *)&bs[off] = socketfd;
off += sizeof(int);
if (bs)
*(sig_atomic_t *)&bs[off] = connection;
off += sizeof(sig_atomic_t);
if (bs)
*(int *)&bs[off] = connected;
off += sizeof(int);
if (bs)
*(size_t *)&bs[off] = connections_ptr;
off += sizeof(size_t);
if (bs)
*(size_t *)&bs[off] = connections_used;
off += sizeof(size_t);
if (bs)
memcpy(&bs[off], connections, connections_used * sizeof(*connections));
off += connections_used * sizeof(*connections);
for (i = 0; i < connections_used; i++) {
if (connections[i] >= 0) {
off += message_marshal(&inbound[i], bs ? &bs[off] : NULL);
off += ring_marshal(&outbound[i], bs ? &bs[off] : NULL);
}
}
if (bs)
*(int *)&bs[off] = method;
off += sizeof(int);
if (bs)
*(int *)&bs[off] = sitename != NULL;
off += sizeof(int);
if (sitename) {
n = strlen(sitename) + 1;
if (bs)
memcpy(&bs[off], sitename, n);
off += n;
}
if (bs)
*(int *)&bs[off] = preserve;
off += sizeof(int);
return off;
}
/**
* Unmarshal the state
*
* @param buf Buffer for the marshalled data
* @return The number of unmarshalled bytes, 0 on error
*/
size_t
state_unmarshal(const void *restrict buf)
{
size_t off = 0, i, n;
const char *restrict bs = buf;
connections = NULL;
inbound = NULL;
if (bs[off]) {
n = strlen(&bs[off]) + 1;
if (!(argv0_real = memdup(&bs[off], n)))
return 0;
off += n;
} else {
off += 1;
}
outputs_n = *(const size_t *)&bs[off];
off += sizeof(size_t);
outputs = calloc(outputs_n, sizeof(*outputs));
if (!outputs)
return 0;
for (i = 0; i < outputs_n; i++) {
off += n = output_unmarshal(outputs + i, &bs[off]);
if (!n)
return 0;
}
socketfd = *(const int *)&bs[off];
off += sizeof(int);
connection = *(const sig_atomic_t *)&bs[off];
off += sizeof(sig_atomic_t);
connected = *(const int *)&bs[off];
off += sizeof(int);
connections_ptr = *(const size_t *)&bs[off];
off += sizeof(size_t);
connections_alloc = connections_used = *(const size_t *)&bs[off];
off += sizeof(size_t);
if (connections_used > 0) {
connections = memdup(&bs[off], connections_used * sizeof(*connections));
if (!connections)
return 0;
off += connections_used * sizeof(*connections);
inbound = malloc(connections_used * sizeof(*inbound));
if (!inbound)
return 0;
outbound = malloc(connections_used * sizeof(*outbound));
if (!outbound)
return 0;
}
for (i = 0; i < connections_used; i++) {
if (connections[i] >= 0) {
off += n = message_unmarshal(&inbound[i], &bs[off]);
if (!n)
return 0;
off += n = ring_unmarshal(&outbound[i], &bs[off]);
if (!n)
return 0;
}
}
method = *(const int *)&bs[off];
off += sizeof(int);
if (*(const int *)&bs[off]) {
off += sizeof(int);
n = strlen(&bs[off]) + 1;
if (!(sitename = memdup(&bs[off], n)))
return 0;
off += n;
} else {
off += sizeof(int);
}
preserve = *(const int *)&bs[off];
off += sizeof(int);
return off;
}
#if defined(__clang__)
# pragma GCC diagnostic pop
#endif
