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/*
htop - Header.c
(C) 2004-2011 Hisham H. Muhammad
Released under the GNU GPLv2, see the COPYING file
in the source distribution for its full text.
*/
#include "Header.h"
#include <stdbool.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "CRT.h"
#include "CPUMeter.h"
#include "DynamicMeter.h"
#include "Macros.h"
#include "Object.h"
#include "Platform.h"
#include "ProvideCurses.h"
#include "XUtils.h"
Header* Header_new(ProcessList* pl, Settings* settings, int nrColumns) {
Header* this = xCalloc(1, sizeof(Header));
this->columns = xCalloc(nrColumns, sizeof(Vector*));
this->settings = settings;
this->pl = pl;
this->nrColumns = nrColumns;
Header_forEachColumn(this, i) {
this->columns[i] = Vector_new(Class(Meter), true, DEFAULT_SIZE);
}
return this;
}
void Header_delete(Header* this) {
Header_forEachColumn(this, i) {
Vector_delete(this->columns[i]);
}
free(this->columns);
free(this);
}
void Header_populateFromSettings(Header* this) {
Header_forEachColumn(this, col) {
const MeterColumnSettings* colSettings = &this->settings->columns[col];
for (int i = 0; i < colSettings->len; i++) {
if (!Header_addMeterByName(this, colSettings->names[i], col)) {
continue;
}
if (colSettings->modes[i] != 0) {
Header_setMode(this, i, colSettings->modes[i], col);
}
}
}
Header_calculateHeight(this);
}
void Header_writeBackToSettings(const Header* this) {
Header_forEachColumn(this, col) {
MeterColumnSettings* colSettings = &this->settings->columns[col];
String_freeArray(colSettings->names);
free(colSettings->modes);
const Vector* vec = this->columns[col];
int len = Vector_size(vec);
colSettings->names = xCalloc(len + 1, sizeof(char*));
colSettings->modes = xCalloc(len, sizeof(int));
colSettings->len = len;
for (int i = 0; i < len; i++) {
const Meter* meter = (Meter*) Vector_get(vec, i);
char* name;
if (meter->param && As_Meter(meter) == &DynamicMeter_class) {
const char* dynamic = DynamicMeter_lookup(this->pl->dynamicMeters, meter->param);
xAsprintf(&name, "%s(%s)", As_Meter(meter)->name, dynamic);
} else if (meter->param && As_Meter(meter) == &CPUMeter_class) {
xAsprintf(&name, "%s(%u)", As_Meter(meter)->name, meter->param);
} else {
xAsprintf(&name, "%s", As_Meter(meter)->name);
}
colSettings->names[i] = name;
colSettings->modes[i] = meter->mode;
}
}
}
bool Header_addMeterByName(Header* this, const char* name, int column) {
Vector* meters = this->columns[column];
char* paren = strchr(name, '(');
unsigned int param = 0;
if (paren) {
char* end, dynamic[32] = {0};
int ok = sscanf(paren, "(%10u)", ¶m); // CPUMeter
if (!ok) {
if (sscanf(paren, "(%30s)", dynamic)) { // DynamicMeter
if ((end = strrchr(dynamic, ')')) == NULL)
return false; // indicate htoprc parse failure
*end = '\0';
if (!DynamicMeter_search(this->pl->dynamicMeters, dynamic, ¶m))
return false; // indicates name lookup failure
}
}
*paren = '\0';
}
for (const MeterClass* const* type = Platform_meterTypes; *type; type++) {
if (String_eq(name, (*type)->name)) {
Meter* meter = Meter_new(this->pl, param, *type);
Vector_add(meters, meter);
break;
}
}
if (paren)
*paren = '(';
return true;
}
void Header_setMode(Header* this, int i, MeterModeId mode, int column) {
Vector* meters = this->columns[column];
if (i >= Vector_size(meters))
return;
Meter* meter = (Meter*) Vector_get(meters, i);
Meter_setMode(meter, mode);
}
Meter* Header_addMeterByClass(Header* this, const MeterClass* type, unsigned int param, int column) {
Vector* meters = this->columns[column];
Meter* meter = Meter_new(this->pl, param, type);
Vector_add(meters, meter);
return meter;
}
int Header_size(const Header* this, int column) {
const Vector* meters = this->columns[column];
return Vector_size(meters);
}
MeterModeId Header_readMeterMode(const Header* this, int i, int column) {
const Vector* meters = this->columns[column];
const Meter* meter = (const Meter*) Vector_get(meters, i);
return meter->mode;
}
void Header_reinit(Header* this) {
Header_forEachColumn(this, col) {
for (int i = 0; i < Vector_size(this->columns[col]); i++) {
Meter* meter = (Meter*) Vector_get(this->columns[col], i);
if (Meter_initFn(meter)) {
Meter_init(meter);
}
}
}
}
void Header_draw(const Header* this) {
const int height = this->height;
const int pad = this->pad;
attrset(CRT_colors[RESET_COLOR]);
for (int y = 0; y < height; y++) {
mvhline(y, 0, ' ', COLS);
}
const int width = COLS / this->nrColumns - pad;
int x = pad;
Header_forEachColumn(this, col) {
Vector* meters = this->columns[col];
for (int y = (pad / 2), i = 0; i < Vector_size(meters); i++) {
Meter* meter = (Meter*) Vector_get(meters, i);
int actualWidth;
if (meter->mode == TEXT_METERMODE)
actualWidth = meter->columnWidthCount * width + (meter->columnWidthCount - 1) * (2 * pad + 1);
else
actualWidth = width;
assert(meter->draw);
meter->draw(meter, x, y, actualWidth);
y += meter->h;
}
x += width + pad;
}
}
void Header_updateData(Header* this) {
Header_forEachColumn(this, col) {
Vector* meters = this->columns[col];
int items = Vector_size(meters);
for (int i = 0; i < items; i++) {
Meter* meter = (Meter*) Vector_get(meters, i);
Meter_updateValues(meter);
}
}
}
/*
* Calculate how many columns the current meter is allowed to span,
* by counting how many columns to the right are empty or contain a BlankMeter.
* Returns the number of columns to span, i.e. if the direct neighbor is occupied 1.
*/
static int calcColumnWidthCount(const Header* this, const Meter* curMeter, const int pad, const int curColumn, const int curHeight) {
for (int i = curColumn + 1; i < this->nrColumns; i++) {
const Vector* meters = this->columns[i];
int height = pad;
for (int j = 0; j < Vector_size(meters); j++) {
const Meter* meter = (const Meter*) Vector_get(meters, j);
if (height >= curHeight + curMeter->h)
break;
height += meter->h;
if (height <= curHeight)
continue;
if (!Object_isA((const Object*) meter, (const ObjectClass*) &BlankMeter_class))
return i - curColumn;
}
}
return this->nrColumns - curColumn;
}
int Header_calculateHeight(Header* this) {
const int pad = this->settings->headerMargin ? 2 : 0;
int maxHeight = pad;
Header_forEachColumn(this, col) {
const Vector* meters = this->columns[col];
int height = pad;
for (int i = 0; i < Vector_size(meters); i++) {
Meter* meter = (Meter*) Vector_get(meters, i);
meter->columnWidthCount = calcColumnWidthCount(this, meter, pad, col, height);
height += meter->h;
}
maxHeight = MAXIMUM(maxHeight, height);
}
this->height = maxHeight;
this->pad = pad;
return maxHeight;
}
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